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[/] [oms8051mini/] [trunk/] [rtl/] [msg_handler/] [msg_handler.v] - Rev 35
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////////////////////////////////////////////////////////////////////// //// //// //// UART Message Handler Module //// //// //// //// This file is part of the oms8051mini cores project //// //// http://www.opencores.org/cores/oms8051min/ //// //// //// //// Description //// //// Uart Message Handler definitions. //// //// //// //// To Do: //// //// nothing //// //// //// //// Author(s): //// //// - Dinesh Annayya, dinesha@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// Revision: //// //// v-0: 27 Nov 2016 //// //// A. rtl file picked from //// //// http://www.opencores.org/cores/uart2spi/ //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// module msg_handler ( reset_n , sys_clk , // UART-TX Information tx_data_avail, tx_rd, tx_data, // UART-RX Information rx_ready, rx_wr, rx_data, // Towards Register Interface reg_addr, reg_wr, reg_wdata, reg_req, reg_ack, reg_rdata ); // Define the Message Hanlde States `define IDLE 4'h0 `define IDLE_TX_MSG1 4'h1 `define IDLE_TX_MSG2 4'h2 `define RX_CMD_PHASE 4'h3 `define WR_ADR_PHASE 4'h4 `define WR_DATA_PHASE 4'h5 `define SEND_WR_REQ 4'h6 `define RD_ADDR_PHASE 4'h7 `define SEND_RD_REQ 4'h8 `define SEND_RD_DATA 4'h9 `define TX_MSG 4'hA `define BREAK_CHAR 8'h0A //--------------------------------- // Global Dec // --------------------------------- input reset_n ; // line reset input sys_clk ; // line clock //-------------------------------------- // UART TXD Path // ------------------------------------- output tx_data_avail ; // Indicate valid TXD Data available output [7:0] tx_data ; // TXD Data to be transmited input tx_rd ; // Indicate TXD Data Been Read //-------------------------------------- // UART RXD Path // ------------------------------------- output rx_ready ; // Indicate Ready to accept the Read Data input [7:0] rx_data ; // RXD Data input rx_wr ; // Valid RXD Data //--------------------------------------- // Control Unit interface // -------------------------------------- output [15:0] reg_addr ; // Operend-1 output [7:0] reg_wdata ; // Operend-2 output reg_req ; // Register Request output reg_wr ; // 1 -> write; 0 -> read input reg_ack ; // Register Ack input [7:0] reg_rdata ; // Local Wire/Register Decleration // // reg tx_data_avail ; reg [7:0] tx_data ; reg [16*8-1:0] TxMsgBuf ; // 16 Byte Tx Message Buffer reg [4:0] TxMsgSize ; reg [4:0] RxMsgCnt ; // Count the Receive Message Count reg [3:0] State ; reg [3:0] NextState ; reg [15:0] cmd ; // command reg [15:0] reg_addr ; // reg_addr reg [7:0] reg_wdata ; // reg_addr reg reg_wr ; // 1 -> Reg Write request, 0 -> Read Requestion reg reg_req ; // 1 -> Register request wire rx_ready = 1; /**************************************************************** * UART Message Hanlding Steps * * 1. On Reset Or Unknown command, Send the Default Message * Select Option: * wr <addr> <data> * rd <addr> * 2. Wait for User command <wr/rd> * 3. On <wr> command move to write address phase; * phase * A. After write address phase move to write data phase * B. After write data phase, once user press \r command ; send register req * and write request and address + data * C. On receiving register ack response; send <success> message back and move * to state-2 * 3. On <rd> command move to read address phase; * A. After read address phase , once user press '\r' command; send * register req , read request * C. On receiving register ack response; send <response + read_data> message and move * to state-2 * *****************************************************************/ always @(negedge reset_n or posedge sys_clk) begin if(reset_n == 1'b0) begin tx_data_avail <= 0; reg_req <= 0; State <= `IDLE; NextState <= `IDLE; end else begin case(State) // Send Default Message `IDLE: begin TxMsgBuf <= "Command Format:\n"; // Align to 16 character format by appending space character TxMsgSize <= 16; tx_data_avail <= 0; State <= `TX_MSG; NextState <= `IDLE_TX_MSG1; end // Send Default Message (Contd..) `IDLE_TX_MSG1: begin TxMsgBuf <= "wm <ad> <data>\n "; // Align to 16 character format by appending space character TxMsgSize <= 15; tx_data_avail <= 0; State <= `TX_MSG; NextState <= `IDLE_TX_MSG2; end // Send Default Message (Contd..) `IDLE_TX_MSG2: begin TxMsgBuf <= "rm <ad>\n>> "; // Align to 16 character format by appending space character TxMsgSize <= 10; tx_data_avail <= 0; RxMsgCnt <= 0; State <= `TX_MSG; NextState <= `RX_CMD_PHASE; end // Wait for Response `RX_CMD_PHASE: begin if(rx_wr == 1) begin //if(RxMsgCnt == 0 && rx_data == " ") begin // Ignore the same if(RxMsgCnt == 0 && rx_data == 8'h20) begin // Ignore the same //end else if(RxMsgCnt > 0 && rx_data == " ") begin // Check the command end else if(RxMsgCnt > 0 && rx_data == 8'h20) begin // Check the command //if(cmd == "wm") begin if(cmd == 16'h776D) begin RxMsgCnt <= 0; reg_addr <= 0; reg_wdata <= 0; State <= `WR_ADR_PHASE; //end else if(cmd == "rm") begin end else if(cmd == 16'h726D) begin reg_addr <= 0; RxMsgCnt <= 0; State <= `RD_ADDR_PHASE; end else begin // Unknow command State <= `IDLE; end //end else if(rx_data == "\n") begin // Error State end else if(rx_data == `BREAK_CHAR) begin // Error State State <= `IDLE; end else begin cmd <= (cmd << 8) | rx_data ; RxMsgCnt <= RxMsgCnt+1; end end end // Write Address Phase `WR_ADR_PHASE: begin if(rx_wr == 1) begin //if(RxMsgCnt == 0 && rx_data == " ") begin // Ignore the Space character if(RxMsgCnt == 0 && rx_data == 8'h20) begin // Ignore the Space character //end else if(RxMsgCnt > 0 && rx_data == " ") begin // Move to write data phase end else if(RxMsgCnt > 0 && rx_data == 8'h20) begin // Move to write data phase State <= `WR_DATA_PHASE; //end else if(rx_data == "\n") begin // Error State end else if(rx_data == `BREAK_CHAR) begin // Error State State <= `IDLE; end else begin reg_addr <= (reg_addr << 4) | char2hex(rx_data); RxMsgCnt <= RxMsgCnt+1; end end end // Write Data Phase `WR_DATA_PHASE: begin if(rx_wr == 1) begin //if(rx_data == " ") begin // Ignore the Space character if(rx_data == 8'h20) begin // Ignore the Space character //end else if(rx_data == "\n") begin // Error State end else if(rx_data == `BREAK_CHAR) begin // Error State State <= `SEND_WR_REQ; reg_wr <= 1'b1; // Write request reg_req <= 1'b1; end else begin // A to F reg_wdata <= (reg_wdata << 4) | char2hex(rx_data); end end end `SEND_WR_REQ: begin if(reg_ack) begin reg_req <= 1'b0; TxMsgBuf <= "cmd success\n>> "; // Align to 16 character format by appending space character TxMsgSize <= 14; tx_data_avail <= 0; State <= `TX_MSG; NextState <= `RX_CMD_PHASE; end end // Write Address Phase `RD_ADDR_PHASE: begin if(rx_wr == 1) begin //if(rx_data == " ") begin // Ignore the Space character if(rx_data == 8'h20) begin // Ignore the Space character //end else if(rx_data == "\n") begin // Error State end else if(rx_data == `BREAK_CHAR) begin // Error State State <= `SEND_RD_REQ; reg_wr <= 1'b0; // Read request reg_req <= 1'b1; // Reg Request end else begin // A to F reg_addr <= (reg_addr << 4) | char2hex(rx_data); RxMsgCnt <= RxMsgCnt+1; end end end `SEND_RD_REQ: begin if(reg_ack) begin reg_req <= 1'b0; TxMsgBuf <= "Response: "; // Align to 16 character format by appending space character TxMsgSize <= 10; tx_data_avail <= 0; State <= `TX_MSG; NextState <= `SEND_RD_DATA; end end `SEND_RD_DATA: begin // Wait for Operation Completion TxMsgBuf[10*8-1:9*8] <= hex2char(reg_rdata[7:4]); TxMsgBuf[9*8-1:8*8] <= hex2char(reg_rdata[3:0]); TxMsgBuf[8*8-1:7*8] <= "\n"; TxMsgSize <= 3; tx_data_avail <= 0; State <= `TX_MSG; NextState <= `RX_CMD_PHASE; end // Send Default Message (Contd..) `TX_MSG: begin tx_data_avail <= 1; tx_data <= TxMsgBuf[16*8-1:15*8]; if(TxMsgSize == 0) begin tx_data_avail <= 0; State <= NextState; end else if(tx_rd) begin TxMsgBuf <= TxMsgBuf << 8; TxMsgSize <= TxMsgSize -1; end end endcase end end // Character to hex number function [3:0] char2hex; input [7:0] data_in; case (data_in) 8'h30: char2hex = 4'h0; // character '0' 8'h31: char2hex = 4'h1; // character '1' 8'h32: char2hex = 4'h2; // character '2' 8'h33: char2hex = 4'h3; // character '3' 8'h34: char2hex = 4'h4; // character '4' 8'h35: char2hex = 4'h5; // character '5' 8'h36: char2hex = 4'h6; // character '6' 8'h37: char2hex = 4'h7; // character '7' 8'h38: char2hex = 4'h8; // character '8' 8'h39: char2hex = 4'h9; // character '9' 8'h41: char2hex = 4'hA; // character 'A' 8'h42: char2hex = 4'hB; // character 'B' 8'h43: char2hex = 4'hC; // character 'C' 8'h44: char2hex = 4'hD; // character 'D' 8'h45: char2hex = 4'hE; // character 'E' 8'h46: char2hex = 4'hF; // character 'F' 8'h61: char2hex = 4'hA; // character 'a' 8'h62: char2hex = 4'hB; // character 'b' 8'h63: char2hex = 4'hC; // character 'c' 8'h64: char2hex = 4'hD; // character 'd' 8'h65: char2hex = 4'hE; // character 'e' 8'h66: char2hex = 4'hF; // character 'f' default : char2hex = 4'hF; endcase endfunction // Hex to Asci Character function [7:0] hex2char; input [3:0] data_in; case (data_in) 4'h0: hex2char = 8'h30; // character '0' 4'h1: hex2char = 8'h31; // character '1' 4'h2: hex2char = 8'h32; // character '2' 4'h3: hex2char = 8'h33; // character '3' 4'h4: hex2char = 8'h34; // character '4' 4'h5: hex2char = 8'h35; // character '5' 4'h6: hex2char = 8'h36; // character '6' 4'h7: hex2char = 8'h37; // character '7' 4'h8: hex2char = 8'h38; // character '8' 4'h9: hex2char = 8'h39; // character '9' 4'hA: hex2char = 8'h41; // character 'A' 4'hB: hex2char = 8'h42; // character 'B' 4'hC: hex2char = 8'h43; // character 'C' 4'hD: hex2char = 8'h44; // character 'D' 4'hE: hex2char = 8'h45; // character 'E' 4'hF: hex2char = 8'h46; // character 'F' endcase endfunction endmodule
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