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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [usbhostslave/] [slaveGetPacket.v] - Rev 408
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// File : ../RTL/slaveController/slaveGetpacket.v // Generated : 11/10/06 05:37:25 // From : ../RTL/slaveController/slaveGetpacket.asf // By : FSM2VHDL ver. 5.0.0.9 ////////////////////////////////////////////////////////////////////// //// //// //// slaveGetPacket //// //// //// This file is part of the usbhostslave opencores effort. //// http://www.opencores.org/cores/usbhostslave/ //// //// //// //// Module Description: //// //// //// //// //// To Do: //// //// //// //// //// Author(s): //// //// - Steve Fielding, sfielding@base2designs.com //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2004 Steve Fielding 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 //// //// //// ////////////////////////////////////////////////////////////////////// // `include "timescale.v" `include "usbhostslave_serialinterfaceengine_h.v" `include "usbhostslave_constants_h.v" module slaveGetPacket (ACKRxed, CRCError, RXDataIn, RXDataValid, RXFifoData, RXFifoFull, RXFifoWEn, RXOverflow, RXPacketRdy, RXStreamStatusIn, RXTimeOut, RxPID, SIERxTimeOut, SIERxTimeOutEn, bitStuffError, clk, dataSequence, endPointReady, getPacketEn, rst); input [7:0] RXDataIn; input RXDataValid; input RXFifoFull; input [7:0] RXStreamStatusIn; input SIERxTimeOut; // Single cycle pulse input clk; input endPointReady; input getPacketEn; input rst; output ACKRxed; output CRCError; output [7:0] RXFifoData; output RXFifoWEn; output RXOverflow; output RXPacketRdy; output RXTimeOut; output [3:0] RxPID; output SIERxTimeOutEn; output bitStuffError; output dataSequence; reg ACKRxed, next_ACKRxed; reg CRCError, next_CRCError; wire [7:0] RXDataIn; wire RXDataValid; reg [7:0] RXFifoData, next_RXFifoData; wire RXFifoFull; reg RXFifoWEn, next_RXFifoWEn; reg RXOverflow, next_RXOverflow; reg RXPacketRdy, next_RXPacketRdy; wire [7:0] RXStreamStatusIn; reg RXTimeOut, next_RXTimeOut; reg [3:0] RxPID, next_RxPID; wire SIERxTimeOut; reg SIERxTimeOutEn, next_SIERxTimeOutEn; reg bitStuffError, next_bitStuffError; wire clk; reg dataSequence, next_dataSequence; wire endPointReady; wire getPacketEn; wire rst; // diagram signals declarations reg [7:0]RXByteOld, next_RXByteOld; reg [7:0]RXByteOldest, next_RXByteOldest; reg [7:0]RXByte, next_RXByte; reg [7:0]RXStreamStatus, next_RXStreamStatus; // BINARY ENCODED state machine: slvGetPkt // State codes definitions: `define PROC_PKT_CHK_PID 5'b00000 `define PROC_PKT_HS 5'b00001 `define PROC_PKT_DATA_W_D1 5'b00010 `define PROC_PKT_DATA_CHK_D1 5'b00011 `define PROC_PKT_DATA_W_D2 5'b00100 `define PROC_PKT_DATA_FIN 5'b00101 `define PROC_PKT_DATA_CHK_D2 5'b00110 `define PROC_PKT_DATA_W_D3 5'b00111 `define PROC_PKT_DATA_CHK_D3 5'b01000 `define PROC_PKT_DATA_LOOP_CHK_FIFO 5'b01001 `define PROC_PKT_DATA_LOOP_FIFO_FULL 5'b01010 `define PROC_PKT_DATA_LOOP_W_D 5'b01011 `define START_GP 5'b01100 `define WAIT_PKT 5'b01101 `define CHK_PKT_START 5'b01110 `define WAIT_EN 5'b01111 `define PKT_RDY 5'b10000 `define PROC_PKT_DATA_LOOP_DELAY 5'b10001 `define PROC_PKT_DATA_LOOP_EP_N_RDY 5'b10010 reg [4:0] CurrState_slvGetPkt; reg [4:0] NextState_slvGetPkt; //-------------------------------------------------------------------- // Machine: slvGetPkt //-------------------------------------------------------------------- //---------------------------------- // Next State Logic (combinatorial) //---------------------------------- always @ (RXDataIn or RXStreamStatusIn or RXByte or RXByteOldest or RXByteOld or RXDataValid or SIERxTimeOut or RXStreamStatus or getPacketEn or endPointReady or RXFifoFull or CRCError or bitStuffError or RXOverflow or RXTimeOut or ACKRxed or dataSequence or SIERxTimeOutEn or RxPID or RXPacketRdy or RXFifoWEn or RXFifoData or CurrState_slvGetPkt) begin : slvGetPkt_NextState NextState_slvGetPkt <= CurrState_slvGetPkt; // Set default values for outputs and signals next_CRCError <= CRCError; next_bitStuffError <= bitStuffError; next_RXOverflow <= RXOverflow; next_RXTimeOut <= RXTimeOut; next_ACKRxed <= ACKRxed; next_dataSequence <= dataSequence; next_SIERxTimeOutEn <= SIERxTimeOutEn; next_RXByte <= RXByte; next_RXStreamStatus <= RXStreamStatus; next_RxPID <= RxPID; next_RXPacketRdy <= RXPacketRdy; next_RXByteOldest <= RXByteOldest; next_RXByteOld <= RXByteOld; next_RXFifoWEn <= RXFifoWEn; next_RXFifoData <= RXFifoData; case (CurrState_slvGetPkt) `START_GP: NextState_slvGetPkt <= `WAIT_EN; `WAIT_PKT: begin next_CRCError <= 1'b0; next_bitStuffError <= 1'b0; next_RXOverflow <= 1'b0; next_RXTimeOut <= 1'b0; next_ACKRxed <= 1'b0; next_dataSequence <= 1'b0; next_SIERxTimeOutEn <= 1'b1; if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `CHK_PKT_START; next_RXByte <= RXDataIn; next_RXStreamStatus <= RXStreamStatusIn; end else if (SIERxTimeOut == 1'b1) begin NextState_slvGetPkt <= `PKT_RDY; next_RXTimeOut <= 1'b1; end end `CHK_PKT_START: if (RXStreamStatus == `RX_PACKET_START) begin NextState_slvGetPkt <= `PROC_PKT_CHK_PID; next_RxPID <= RXByte[3:0]; end else begin NextState_slvGetPkt <= `PKT_RDY; next_RXTimeOut <= 1'b1; end `WAIT_EN: begin next_RXPacketRdy <= 1'b0; next_SIERxTimeOutEn <= 1'b0; if (getPacketEn == 1'b1) NextState_slvGetPkt <= `WAIT_PKT; end `PKT_RDY: begin next_RXPacketRdy <= 1'b1; NextState_slvGetPkt <= `WAIT_EN; end `PROC_PKT_CHK_PID: if (RXByte[1:0] == `HANDSHAKE) NextState_slvGetPkt <= `PROC_PKT_HS; else if (RXByte[1:0] == `DATA) NextState_slvGetPkt <= `PROC_PKT_DATA_W_D1; else NextState_slvGetPkt <= `PKT_RDY; `PROC_PKT_HS: if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `PKT_RDY; next_RXOverflow <= RXDataIn[`RX_OVERFLOW_BIT]; next_ACKRxed <= RXDataIn[`ACK_RXED_BIT]; end `PROC_PKT_DATA_W_D1: if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `PROC_PKT_DATA_CHK_D1; next_RXByte <= RXDataIn; next_RXStreamStatus <= RXStreamStatusIn; end `PROC_PKT_DATA_CHK_D1: if (RXStreamStatus == `RX_PACKET_STREAM) begin NextState_slvGetPkt <= `PROC_PKT_DATA_W_D2; next_RXByteOldest <= RXByte; end else NextState_slvGetPkt <= `PROC_PKT_DATA_FIN; `PROC_PKT_DATA_W_D2: if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `PROC_PKT_DATA_CHK_D2; next_RXByte <= RXDataIn; next_RXStreamStatus <= RXStreamStatusIn; end `PROC_PKT_DATA_FIN: begin next_CRCError <= RXByte[`CRC_ERROR_BIT]; next_bitStuffError <= RXByte[`BIT_STUFF_ERROR_BIT]; next_dataSequence <= RXByte[`DATA_SEQUENCE_BIT]; NextState_slvGetPkt <= `PKT_RDY; end `PROC_PKT_DATA_CHK_D2: if (RXStreamStatus == `RX_PACKET_STREAM) begin NextState_slvGetPkt <= `PROC_PKT_DATA_W_D3; next_RXByteOld <= RXByte; end else NextState_slvGetPkt <= `PROC_PKT_DATA_FIN; `PROC_PKT_DATA_W_D3: if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `PROC_PKT_DATA_CHK_D3; next_RXByte <= RXDataIn; next_RXStreamStatus <= RXStreamStatusIn; end `PROC_PKT_DATA_CHK_D3: if (RXStreamStatus == `RX_PACKET_STREAM) NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_CHK_FIFO; else NextState_slvGetPkt <= `PROC_PKT_DATA_FIN; `PROC_PKT_DATA_LOOP_CHK_FIFO: if (endPointReady == 1'b0) NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_EP_N_RDY; else if (RXFifoFull == 1'b1) begin NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_FIFO_FULL; next_RXOverflow <= 1'b1; end else begin NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_W_D; next_RXFifoWEn <= 1'b1; next_RXFifoData <= RXByteOldest; next_RXByteOldest <= RXByteOld; next_RXByteOld <= RXByte; end `PROC_PKT_DATA_LOOP_FIFO_FULL: NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_W_D; `PROC_PKT_DATA_LOOP_W_D: begin next_RXFifoWEn <= 1'b0; if ((RXDataValid == 1'b1) && (RXStreamStatusIn == `RX_PACKET_STREAM)) begin NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_DELAY; next_RXByte <= RXDataIn; end else if (RXDataValid == 1'b1) begin NextState_slvGetPkt <= `PROC_PKT_DATA_FIN; next_RXByte <= RXDataIn; end end `PROC_PKT_DATA_LOOP_DELAY: NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_CHK_FIFO; `PROC_PKT_DATA_LOOP_EP_N_RDY: // Discard data NextState_slvGetPkt <= `PROC_PKT_DATA_LOOP_W_D; endcase end //---------------------------------- // Current State Logic (sequential) //---------------------------------- always @ (posedge clk) begin : slvGetPkt_CurrentState if (rst) CurrState_slvGetPkt <= `START_GP; else CurrState_slvGetPkt <= NextState_slvGetPkt; end //---------------------------------- // Registered outputs logic //---------------------------------- always @ (posedge clk) begin : slvGetPkt_RegOutput if (rst) begin RXByteOld <= 8'h00; RXByteOldest <= 8'h00; RXByte <= 8'h00; RXStreamStatus <= 8'h00; RXPacketRdy <= 1'b0; RXFifoWEn <= 1'b0; RXFifoData <= 8'h00; CRCError <= 1'b0; bitStuffError <= 1'b0; RXOverflow <= 1'b0; RXTimeOut <= 1'b0; ACKRxed <= 1'b0; dataSequence <= 1'b0; SIERxTimeOutEn <= 1'b0; RxPID <= 4'h0; end else begin RXByteOld <= next_RXByteOld; RXByteOldest <= next_RXByteOldest; RXByte <= next_RXByte; RXStreamStatus <= next_RXStreamStatus; RXPacketRdy <= next_RXPacketRdy; RXFifoWEn <= next_RXFifoWEn; RXFifoData <= next_RXFifoData; CRCError <= next_CRCError; bitStuffError <= next_bitStuffError; RXOverflow <= next_RXOverflow; RXTimeOut <= next_RXTimeOut; ACKRxed <= next_ACKRxed; dataSequence <= next_dataSequence; SIERxTimeOutEn <= next_SIERxTimeOutEn; RxPID <= next_RxPID; end end endmodule