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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [usbhostslave/] [slavecontroller.v] - Rev 408
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// File : ../RTL/slaveController/slavecontroller.v // Generated : 11/10/06 05:37:25 // From : ../RTL/slaveController/slavecontroller.asf // By : FSM2VHDL ver. 5.0.0.9 ////////////////////////////////////////////////////////////////////// //// //// //// slaveController //// //// //// 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_slavecontrol_h.v" `include "usbhostslave_constants_h.v" module slavecontroller (CRCError, NAKSent, RxByte, RxDataWEn, RxOverflow, RxStatus, RxTimeOut, SCGlobalEn, SOFRxed, USBEndPControlReg, USBEndPNakTransTypeReg, USBEndPTransTypeReg, USBEndP, USBTgtAddress, bitStuffError, clk, clrEPRdy, endPMuxErrorsWEn, endPointReadyToGetPkt, frameNum, getPacketREn, getPacketRdy, rst, sendPacketPID, sendPacketRdy, sendPacketWEn, stallSent, transDone); input CRCError; input [7:0] RxByte; input RxDataWEn; input RxOverflow; input [7:0] RxStatus; input RxTimeOut; input SCGlobalEn; input [4:0] USBEndPControlReg; input [6:0] USBTgtAddress; input bitStuffError; input clk; input getPacketRdy; input rst; input sendPacketRdy; output NAKSent; output SOFRxed; output [1:0] USBEndPNakTransTypeReg; output [1:0] USBEndPTransTypeReg; output [3:0] USBEndP; output clrEPRdy; output endPMuxErrorsWEn; output endPointReadyToGetPkt; output [10:0] frameNum; output getPacketREn; output [3:0] sendPacketPID; output sendPacketWEn; output stallSent; output transDone; wire CRCError; reg NAKSent, next_NAKSent; wire [7:0] RxByte; wire RxDataWEn; wire RxOverflow; wire [7:0] RxStatus; wire RxTimeOut; wire SCGlobalEn; reg SOFRxed, next_SOFRxed; wire [4:0] USBEndPControlReg; reg [1:0] USBEndPNakTransTypeReg, next_USBEndPNakTransTypeReg; reg [1:0] USBEndPTransTypeReg, next_USBEndPTransTypeReg; reg [3:0] USBEndP, next_USBEndP; wire [6:0] USBTgtAddress; wire bitStuffError; wire clk; reg clrEPRdy, next_clrEPRdy; reg endPMuxErrorsWEn, next_endPMuxErrorsWEn; reg endPointReadyToGetPkt, next_endPointReadyToGetPkt; reg [10:0] frameNum, next_frameNum; reg getPacketREn, next_getPacketREn; wire getPacketRdy; wire rst; reg [3:0] sendPacketPID, next_sendPacketPID; wire sendPacketRdy; reg sendPacketWEn, next_sendPacketWEn; reg stallSent, next_stallSent; reg transDone, next_transDone; // diagram signals declarations reg [7:0]PIDByte, next_PIDByte; reg [6:0]USBAddress, next_USBAddress; reg [4:0]USBEndPControlRegCopy, next_USBEndPControlRegCopy; reg [7:0]addrEndPTemp, next_addrEndPTemp; reg [7:0]endpCRCTemp, next_endpCRCTemp; reg [1:0]tempUSBEndPTransTypeReg, next_tempUSBEndPTransTypeReg; // BINARY ENCODED state machine: slvCntrl // State codes definitions: `define WAIT_RX1 5'b00000 `define FIN_SC 5'b00001 `define GET_TOKEN_WAIT_CRC 5'b00010 `define GET_TOKEN_WAIT_ADDR 5'b00011 `define GET_TOKEN_WAIT_STOP 5'b00100 `define CHK_PID 5'b00101 `define GET_TOKEN_CHK_SOF 5'b00110 `define PID_ERROR 5'b00111 `define CHK_RDY 5'b01000 `define IN_NAK_STALL 5'b01001 `define IN_CHK_RDY 5'b01010 `define SETUP_OUT_CHK 5'b01011 `define SETUP_OUT_SEND 5'b01100 `define SETUP_OUT_GET_PKT 5'b01101 `define START_S1 5'b01110 `define GET_TOKEN_DELAY 5'b01111 `define GET_TOKEN_CHK_ADDR 5'b10000 `define IN_RESP_GET_RESP 5'b10001 `define IN_RESP_DATA 5'b10010 `define IN_RESP_CHK_ISO 5'b10011 reg [4:0] CurrState_slvCntrl; reg [4:0] NextState_slvCntrl; //-------------------------------------------------------------------- // Machine: slvCntrl //-------------------------------------------------------------------- //---------------------------------- // Next State Logic (combinatorial) //---------------------------------- always @ (RxByte or tempUSBEndPTransTypeReg or endpCRCTemp or addrEndPTemp or USBEndPControlReg or RxDataWEn or RxStatus or PIDByte or USBEndPControlRegCopy or NAKSent or sendPacketRdy or getPacketRdy or CRCError or bitStuffError or RxOverflow or RxTimeOut or USBEndP or USBAddress or USBTgtAddress or SCGlobalEn or stallSent or SOFRxed or transDone or clrEPRdy or endPMuxErrorsWEn or getPacketREn or sendPacketWEn or sendPacketPID or USBEndPTransTypeReg or USBEndPNakTransTypeReg or frameNum or endPointReadyToGetPkt or CurrState_slvCntrl) begin : slvCntrl_NextState NextState_slvCntrl <= CurrState_slvCntrl; // Set default values for outputs and signals next_stallSent <= stallSent; next_NAKSent <= NAKSent; next_SOFRxed <= SOFRxed; next_PIDByte <= PIDByte; next_transDone <= transDone; next_clrEPRdy <= clrEPRdy; next_endPMuxErrorsWEn <= endPMuxErrorsWEn; next_tempUSBEndPTransTypeReg <= tempUSBEndPTransTypeReg; next_getPacketREn <= getPacketREn; next_sendPacketWEn <= sendPacketWEn; next_sendPacketPID <= sendPacketPID; next_USBEndPTransTypeReg <= USBEndPTransTypeReg; next_USBEndPNakTransTypeReg <= USBEndPNakTransTypeReg; next_endpCRCTemp <= endpCRCTemp; next_addrEndPTemp <= addrEndPTemp; next_frameNum <= frameNum; next_USBAddress <= USBAddress; next_USBEndP <= USBEndP; next_USBEndPControlRegCopy <= USBEndPControlRegCopy; next_endPointReadyToGetPkt <= endPointReadyToGetPkt; case (CurrState_slvCntrl) `WAIT_RX1: begin next_stallSent <= 1'b0; next_NAKSent <= 1'b0; next_SOFRxed <= 1'b0; if (RxDataWEn == 1'b1 && RxStatus == `RX_PACKET_START && RxByte[1:0] == `TOKEN) begin NextState_slvCntrl <= `GET_TOKEN_WAIT_ADDR; next_PIDByte <= RxByte; end end `FIN_SC: begin next_transDone <= 1'b0; next_clrEPRdy <= 1'b0; next_endPMuxErrorsWEn <= 1'b0; NextState_slvCntrl <= `WAIT_RX1; end `CHK_PID: if (PIDByte[3:0] == `SETUP) begin NextState_slvCntrl <= `SETUP_OUT_GET_PKT; next_tempUSBEndPTransTypeReg <= `SC_SETUP_TRANS; next_getPacketREn <= 1'b1; end else if (PIDByte[3:0] == `OUT) begin NextState_slvCntrl <= `SETUP_OUT_GET_PKT; next_tempUSBEndPTransTypeReg <= `SC_OUTDATA_TRANS; next_getPacketREn <= 1'b1; end else if ((PIDByte[3:0] == `IN) && (USBEndPControlRegCopy[`ENDPOINT_ISO_ENABLE_BIT] == 1'b0)) begin NextState_slvCntrl <= `IN_CHK_RDY; next_tempUSBEndPTransTypeReg <= `SC_IN_TRANS; end else if (((PIDByte[3:0] == `IN) && (USBEndPControlRegCopy [`ENDPOINT_READY_BIT] == 1'b1)) && (USBEndPControlRegCopy [`ENDPOINT_OUTDATA_SEQUENCE_BIT] == 1'b0)) begin NextState_slvCntrl <= `IN_RESP_DATA; next_tempUSBEndPTransTypeReg <= `SC_IN_TRANS; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `DATA0; end else if ((PIDByte[3:0] == `IN) && (USBEndPControlRegCopy [`ENDPOINT_READY_BIT] == 1'b1)) begin NextState_slvCntrl <= `IN_RESP_DATA; next_tempUSBEndPTransTypeReg <= `SC_IN_TRANS; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `DATA1; end else if (PIDByte[3:0] == `IN) begin NextState_slvCntrl <= `CHK_RDY; next_tempUSBEndPTransTypeReg <= `SC_IN_TRANS; end else NextState_slvCntrl <= `PID_ERROR; `PID_ERROR: NextState_slvCntrl <= `WAIT_RX1; `CHK_RDY: if (USBEndPControlRegCopy [`ENDPOINT_READY_BIT] == 1'b1) begin NextState_slvCntrl <= `FIN_SC; next_transDone <= 1'b1; next_clrEPRdy <= 1'b1; next_USBEndPTransTypeReg <= tempUSBEndPTransTypeReg; next_endPMuxErrorsWEn <= 1'b1; end else if (NAKSent == 1'b1) begin NextState_slvCntrl <= `FIN_SC; next_USBEndPNakTransTypeReg <= tempUSBEndPTransTypeReg; next_endPMuxErrorsWEn <= 1'b1; end else NextState_slvCntrl <= `FIN_SC; `SETUP_OUT_CHK: if (USBEndPControlRegCopy [`ENDPOINT_READY_BIT] == 1'b0) begin NextState_slvCntrl <= `SETUP_OUT_SEND; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `NAK; next_NAKSent <= 1'b1; end else if (USBEndPControlRegCopy [`ENDPOINT_SEND_STALL_BIT] == 1'b1) begin NextState_slvCntrl <= `SETUP_OUT_SEND; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `STALL; next_stallSent <= 1'b1; end else begin NextState_slvCntrl <= `SETUP_OUT_SEND; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `ACK; end `SETUP_OUT_SEND: begin next_sendPacketWEn <= 1'b0; if (sendPacketRdy == 1'b1) NextState_slvCntrl <= `CHK_RDY; end `SETUP_OUT_GET_PKT: begin next_getPacketREn <= 1'b0; if ((getPacketRdy == 1'b1) && (USBEndPControlRegCopy [`ENDPOINT_ISO_ENABLE_BIT] == 1'b1)) NextState_slvCntrl <= `CHK_RDY; else if ((getPacketRdy == 1'b1) && (CRCError == 1'b0 && bitStuffError == 1'b0 && RxOverflow == 1'b0 && RxTimeOut == 1'b0)) NextState_slvCntrl <= `SETUP_OUT_CHK; else if (getPacketRdy == 1'b1) NextState_slvCntrl <= `CHK_RDY; end `IN_NAK_STALL: begin next_sendPacketWEn <= 1'b0; if (sendPacketRdy == 1'b1) NextState_slvCntrl <= `CHK_RDY; end `IN_CHK_RDY: if (USBEndPControlRegCopy [`ENDPOINT_READY_BIT] == 1'b0) begin NextState_slvCntrl <= `IN_NAK_STALL; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `NAK; next_NAKSent <= 1'b1; end else if (USBEndPControlRegCopy [`ENDPOINT_SEND_STALL_BIT] == 1'b1) begin NextState_slvCntrl <= `IN_NAK_STALL; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `STALL; next_stallSent <= 1'b1; end else if (USBEndPControlRegCopy [`ENDPOINT_OUTDATA_SEQUENCE_BIT] == 1'b0) begin NextState_slvCntrl <= `IN_RESP_DATA; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `DATA0; end else begin NextState_slvCntrl <= `IN_RESP_DATA; next_sendPacketWEn <= 1'b1; next_sendPacketPID <= `DATA1; end `IN_RESP_GET_RESP: begin next_getPacketREn <= 1'b0; if (getPacketRdy == 1'b1) NextState_slvCntrl <= `CHK_RDY; end `IN_RESP_DATA: begin next_sendPacketWEn <= 1'b0; if (sendPacketRdy == 1'b1) NextState_slvCntrl <= `IN_RESP_CHK_ISO; end `IN_RESP_CHK_ISO: if (USBEndPControlRegCopy [`ENDPOINT_ISO_ENABLE_BIT] == 1'b1) NextState_slvCntrl <= `CHK_RDY; else begin NextState_slvCntrl <= `IN_RESP_GET_RESP; next_getPacketREn <= 1'b1; end `START_S1: NextState_slvCntrl <= `WAIT_RX1; `GET_TOKEN_WAIT_CRC: if (RxDataWEn == 1'b1 && RxStatus == `RX_PACKET_STREAM) begin NextState_slvCntrl <= `GET_TOKEN_WAIT_STOP; next_endpCRCTemp <= RxByte; end else if (RxDataWEn == 1'b1 && RxStatus != `RX_PACKET_STREAM) NextState_slvCntrl <= `WAIT_RX1; `GET_TOKEN_WAIT_ADDR: if (RxDataWEn == 1'b1 && RxStatus == `RX_PACKET_STREAM) begin NextState_slvCntrl <= `GET_TOKEN_WAIT_CRC; next_addrEndPTemp <= RxByte; end else if (RxDataWEn == 1'b1 && RxStatus != `RX_PACKET_STREAM) NextState_slvCntrl <= `WAIT_RX1; `GET_TOKEN_WAIT_STOP: if ((RxDataWEn == 1'b1) && (RxByte[`CRC_ERROR_BIT] == 1'b0 && RxByte[`BIT_STUFF_ERROR_BIT] == 1'b0 && RxByte [`RX_OVERFLOW_BIT] == 1'b0)) NextState_slvCntrl <= `GET_TOKEN_CHK_SOF; else if (RxDataWEn == 1'b1) NextState_slvCntrl <= `WAIT_RX1; `GET_TOKEN_CHK_SOF: if (PIDByte[3:0] == `SOF) begin NextState_slvCntrl <= `WAIT_RX1; next_frameNum <= {endpCRCTemp[2:0],addrEndPTemp}; next_SOFRxed <= 1'b1; end else begin NextState_slvCntrl <= `GET_TOKEN_DELAY; next_USBAddress <= addrEndPTemp[6:0]; next_USBEndP <= { endpCRCTemp[2:0], addrEndPTemp[7]}; end `GET_TOKEN_DELAY: // Insert delay to allow USBEndP etc to update NextState_slvCntrl <= `GET_TOKEN_CHK_ADDR; `GET_TOKEN_CHK_ADDR: if (USBEndP < `NUM_OF_ENDPOINTS && USBAddress == USBTgtAddress && SCGlobalEn == 1'b1 && USBEndPControlReg[`ENDPOINT_ENABLE_BIT] == 1'b1) begin NextState_slvCntrl <= `CHK_PID; next_USBEndPControlRegCopy <= USBEndPControlReg; next_endPointReadyToGetPkt <= USBEndPControlReg [`ENDPOINT_READY_BIT]; end else NextState_slvCntrl <= `WAIT_RX1; endcase end //---------------------------------- // Current State Logic (sequential) //---------------------------------- always @ (posedge clk) begin : slvCntrl_CurrentState if (rst) CurrState_slvCntrl <= `START_S1; else CurrState_slvCntrl <= NextState_slvCntrl; end //---------------------------------- // Registered outputs logic //---------------------------------- always @ (posedge clk) begin : slvCntrl_RegOutput if (rst) begin tempUSBEndPTransTypeReg <= 2'b00; addrEndPTemp <= 8'h00; endpCRCTemp <= 8'h00; USBAddress <= 7'b0000000; PIDByte <= 8'h00; USBEndPControlRegCopy <= 5'b00000; transDone <= 1'b0; getPacketREn <= 1'b0; sendPacketPID <= 4'b0; sendPacketWEn <= 1'b0; clrEPRdy <= 1'b0; USBEndPTransTypeReg <= 2'b00; USBEndPNakTransTypeReg <= 2'b00; NAKSent <= 1'b0; stallSent <= 1'b0; SOFRxed <= 1'b0; endPMuxErrorsWEn <= 1'b0; frameNum <= 11'b00000000000; USBEndP <= 4'h0; endPointReadyToGetPkt <= 1'b0; end else begin tempUSBEndPTransTypeReg <= next_tempUSBEndPTransTypeReg; addrEndPTemp <= next_addrEndPTemp; endpCRCTemp <= next_endpCRCTemp; USBAddress <= next_USBAddress; PIDByte <= next_PIDByte; USBEndPControlRegCopy <= next_USBEndPControlRegCopy; transDone <= next_transDone; getPacketREn <= next_getPacketREn; sendPacketPID <= next_sendPacketPID; sendPacketWEn <= next_sendPacketWEn; clrEPRdy <= next_clrEPRdy; USBEndPTransTypeReg <= next_USBEndPTransTypeReg; USBEndPNakTransTypeReg <= next_USBEndPNakTransTypeReg; NAKSent <= next_NAKSent; stallSent <= next_stallSent; SOFRxed <= next_SOFRxed; endPMuxErrorsWEn <= next_endPMuxErrorsWEn; frameNum <= next_frameNum; USBEndP <= next_USBEndP; endPointReadyToGetPkt <= next_endPointReadyToGetPkt; end end endmodule