URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [orpsocv2/] [bench/] [verilog/] [usbhostslave/] [USBSlaveControlBI_simlib.v] - Rev 862
Go to most recent revision | Compare with Previous | Blame | View Log
////////////////////////////////////////////////////////////////////// //// //// //// USBSlaveControlBI.v //// //// //// //// This file is part of the usbhostslave opencores effort. //// <http://www.opencores.org/cores//> //// //// //// //// 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 "usbSlaveControl_h.v" module USBSlaveControlBI_simlib (address, dataIn, dataOut, writeEn, strobe_i, busClk, rstSyncToBusClk, usbClk, rstSyncToUsbClk, SOFRxedIntOut, resetEventIntOut, resumeIntOut, transDoneIntOut, NAKSentIntOut, vBusDetIntOut, endP0TransTypeReg, endP0NAKTransTypeReg, endP1TransTypeReg, endP1NAKTransTypeReg, endP2TransTypeReg, endP2NAKTransTypeReg, endP3TransTypeReg, endP3NAKTransTypeReg, endP0ControlReg, endP1ControlReg, endP2ControlReg, endP3ControlReg, EP0StatusReg, EP1StatusReg, EP2StatusReg, EP3StatusReg, SCAddrReg, frameNum, connectStateIn, vBusDetectIn, SOFRxedIn, resetEventIn, resumeIntIn, transDoneIn, NAKSentIn, slaveControlSelect, clrEP0Ready, clrEP1Ready, clrEP2Ready, clrEP3Ready, TxLineState, LineDirectControlEn, fullSpeedPol, fullSpeedRate, connectSlaveToHost, SCGlobalEn ); input [4:0] address; input [7:0] dataIn; input writeEn; input strobe_i; input busClk; input rstSyncToBusClk; input usbClk; input rstSyncToUsbClk; output [7:0] dataOut; output SOFRxedIntOut; output resetEventIntOut; output resumeIntOut; output transDoneIntOut; output NAKSentIntOut; output vBusDetIntOut; input [1:0] endP0TransTypeReg; input [1:0] endP0NAKTransTypeReg; input [1:0] endP1TransTypeReg; input [1:0] endP1NAKTransTypeReg; input [1:0] endP2TransTypeReg; input [1:0] endP2NAKTransTypeReg; input [1:0] endP3TransTypeReg; input [1:0] endP3NAKTransTypeReg; output [4:0] endP0ControlReg; output [4:0] endP1ControlReg; output [4:0] endP2ControlReg; output [4:0] endP3ControlReg; input [7:0] EP0StatusReg; input [7:0] EP1StatusReg; input [7:0] EP2StatusReg; input [7:0] EP3StatusReg; output [6:0] SCAddrReg; input [10:0] frameNum; input [1:0] connectStateIn; input vBusDetectIn; input SOFRxedIn; input resetEventIn; input resumeIntIn; input transDoneIn; input NAKSentIn; input slaveControlSelect; input clrEP0Ready; input clrEP1Ready; input clrEP2Ready; input clrEP3Ready; output [1:0] TxLineState; output LineDirectControlEn; output fullSpeedPol; output fullSpeedRate; output connectSlaveToHost; output SCGlobalEn; wire [4:0] address; wire [7:0] dataIn; wire writeEn; wire strobe_i; wire busClk; wire rstSyncToBusClk; wire usbClk; wire rstSyncToUsbClk; reg [7:0] dataOut; reg SOFRxedIntOut; reg resetEventIntOut; reg resumeIntOut; reg transDoneIntOut; reg NAKSentIntOut; reg vBusDetIntOut; wire [1:0] endP0TransTypeReg; wire [1:0] endP0NAKTransTypeReg; wire [1:0] endP1TransTypeReg; wire [1:0] endP1NAKTransTypeReg; wire [1:0] endP2TransTypeReg; wire [1:0] endP2NAKTransTypeReg; wire [1:0] endP3TransTypeReg; wire [1:0] endP3NAKTransTypeReg; reg [4:0] endP0ControlReg; reg [4:0] endP0ControlReg1; reg [4:0] endP1ControlReg; reg [4:0] endP1ControlReg1; reg [4:0] endP2ControlReg; reg [4:0] endP2ControlReg1; reg [4:0] endP3ControlReg; reg [4:0] endP3ControlReg1; wire [7:0] EP0StatusReg; wire [7:0] EP1StatusReg; wire [7:0] EP2StatusReg; wire [7:0] EP3StatusReg; reg [6:0] SCAddrReg; reg [3:0] TxEndPReg; wire [10:0] frameNum; wire [1:0] connectStateIn; wire SOFRxedIn; wire resetEventIn; wire resumeIntIn; wire transDoneIn; wire NAKSentIn; wire slaveControlSelect; wire clrEP0Ready; wire clrEP1Ready; wire clrEP2Ready; wire clrEP3Ready; reg [1:0] TxLineState; reg [1:0] TxLineState_reg1; reg LineDirectControlEn; reg LineDirectControlEn_reg1; reg fullSpeedPol; reg fullSpeedPol_reg1; reg fullSpeedRate; reg fullSpeedRate_reg1; reg connectSlaveToHost; reg connectSlaveToHost_reg1; reg SCGlobalEn; reg SCGlobalEn_reg1; //internal wire and regs reg [6:0] SCControlReg; reg clrVBusDetReq; reg clrNAKReq; reg clrSOFReq; reg clrResetReq; reg clrResInReq; reg clrTransDoneReq; reg SOFRxedInt; reg resetEventInt; reg resumeInt; reg transDoneInt; reg vBusDetInt; reg NAKSentInt; reg [5:0] interruptMaskReg; reg EP0SetReady; reg EP1SetReady; reg EP2SetReady; reg EP3SetReady; reg EP0SendStall; reg EP1SendStall; reg EP2SendStall; reg EP3SendStall; reg EP0IsoEn; reg EP1IsoEn; reg EP2IsoEn; reg EP3IsoEn; reg EP0DataSequence; reg EP1DataSequence; reg EP2DataSequence; reg EP3DataSequence; reg EP0Enable; reg EP1Enable; reg EP2Enable; reg EP3Enable; reg EP0Ready; reg EP1Ready; reg EP2Ready; reg EP3Ready; reg [2:0] SOFRxedInExtend; reg [2:0] resetEventInExtend; reg [2:0] resumeIntInExtend; reg [2:0] transDoneInExtend; reg [2:0] NAKSentInExtend; reg [2:0] clrEP0ReadyExtend; reg [2:0] clrEP1ReadyExtend; reg [2:0] clrEP2ReadyExtend; reg [2:0] clrEP3ReadyExtend; //clock domain crossing sync registers //STB = Sync To Busclk reg [4:0] endP0ControlRegSTB; reg [4:0] endP1ControlRegSTB; reg [4:0] endP2ControlRegSTB; reg [4:0] endP3ControlRegSTB; reg [2:0] NAKSentInSTB; reg [2:0] SOFRxedInSTB; reg [2:0] resetEventInSTB; reg [2:0] resumeIntInSTB; reg [2:0] transDoneInSTB; reg [2:0] clrEP0ReadySTB; reg [2:0] clrEP1ReadySTB; reg [2:0] clrEP2ReadySTB; reg [2:0] clrEP3ReadySTB; reg SCGlobalEnSTB; reg [1:0] TxLineStateSTB; reg LineDirectControlEnSTB; reg fullSpeedPolSTB; reg fullSpeedRateSTB; reg connectSlaveToHostSTB; reg [7:0] EP0StatusRegSTB; reg [7:0] EP0StatusRegSTB_reg1; reg [7:0] EP1StatusRegSTB; reg [7:0] EP1StatusRegSTB_reg1; reg [7:0] EP2StatusRegSTB; reg [7:0] EP2StatusRegSTB_reg1; reg [7:0] EP3StatusRegSTB; reg [7:0] EP3StatusRegSTB_reg1; reg [1:0] endP0TransTypeRegSTB; reg [1:0] endP0TransTypeRegSTB_reg1; reg [1:0] endP0NAKTransTypeRegSTB; reg [1:0] endP0NAKTransTypeRegSTB_reg1; reg [1:0] endP1TransTypeRegSTB; reg [1:0] endP1TransTypeRegSTB_reg1; reg [1:0] endP1NAKTransTypeRegSTB; reg [1:0] endP1NAKTransTypeRegSTB_reg1; reg [1:0] endP2TransTypeRegSTB; reg [1:0] endP2TransTypeRegSTB_reg1; reg [1:0] endP2NAKTransTypeRegSTB; reg [1:0] endP2NAKTransTypeRegSTB_reg1; reg [1:0] endP3TransTypeRegSTB; reg [1:0] endP3TransTypeRegSTB_reg1; reg [1:0] endP3NAKTransTypeRegSTB; reg [1:0] endP3NAKTransTypeRegSTB_reg1; reg [10:0] frameNumSTB; reg [10:0] frameNumSTB_reg1; reg [2:0] vBusDetectInSTB; reg [1:0] connectStateInSTB; reg [1:0] connectStateInSTB_reg1; //sync write demux always @(posedge busClk) begin if (rstSyncToBusClk == 1'b1) begin EP0IsoEn <= 1'b0; EP0SendStall <= 1'b0; EP0DataSequence <= 1'b0; EP0Enable <= 1'b0; EP1IsoEn <= 1'b0; EP1SendStall <= 1'b0; EP1DataSequence <= 1'b0; EP1Enable <= 1'b0; EP2IsoEn <= 1'b0; EP2SendStall <= 1'b0; EP2DataSequence <= 1'b0; EP2Enable <= 1'b0; EP3IsoEn <= 1'b0; EP3SendStall <= 1'b0; EP3DataSequence <= 1'b0; EP3Enable <= 1'b0; SCControlReg <= 7'h00; SCAddrReg <= 7'h00; interruptMaskReg <= 6'h00; end else begin clrVBusDetReq <= 1'b0; clrNAKReq <= 1'b0; clrSOFReq <= 1'b0; clrResetReq <= 1'b0; clrResInReq <= 1'b0; clrTransDoneReq <= 1'b0; EP0SetReady <= 1'b0; EP1SetReady <= 1'b0; EP2SetReady <= 1'b0; EP3SetReady <= 1'b0; if (writeEn == 1'b1 && strobe_i == 1'b1 && slaveControlSelect == 1'b1) begin case (address) `EP0_CTRL_REG : begin EP0IsoEn <= dataIn[`ENDPOINT_ISO_ENABLE_BIT]; EP0SendStall <= dataIn[`ENDPOINT_SEND_STALL_BIT]; EP0DataSequence <= dataIn[`ENDPOINT_OUTDATA_SEQUENCE_BIT]; EP0SetReady <= dataIn[`ENDPOINT_READY_BIT]; EP0Enable <= dataIn[`ENDPOINT_ENABLE_BIT]; end `EP1_CTRL_REG : begin EP1IsoEn <= dataIn[`ENDPOINT_ISO_ENABLE_BIT]; EP1SendStall <= dataIn[`ENDPOINT_SEND_STALL_BIT]; EP1DataSequence <= dataIn[`ENDPOINT_OUTDATA_SEQUENCE_BIT]; EP1SetReady <= dataIn[`ENDPOINT_READY_BIT]; EP1Enable <= dataIn[`ENDPOINT_ENABLE_BIT]; end `EP2_CTRL_REG : begin EP2IsoEn <= dataIn[`ENDPOINT_ISO_ENABLE_BIT]; EP2SendStall <= dataIn[`ENDPOINT_SEND_STALL_BIT]; EP2DataSequence <= dataIn[`ENDPOINT_OUTDATA_SEQUENCE_BIT]; EP2SetReady <= dataIn[`ENDPOINT_READY_BIT]; EP2Enable <= dataIn[`ENDPOINT_ENABLE_BIT]; end `EP3_CTRL_REG : begin EP3IsoEn <= dataIn[`ENDPOINT_ISO_ENABLE_BIT]; EP3SendStall <= dataIn[`ENDPOINT_SEND_STALL_BIT]; EP3DataSequence <= dataIn[`ENDPOINT_OUTDATA_SEQUENCE_BIT]; EP3SetReady <= dataIn[`ENDPOINT_READY_BIT]; EP3Enable <= dataIn[`ENDPOINT_ENABLE_BIT]; end `SC_CONTROL_REG : SCControlReg <= dataIn[6:0]; `SC_ADDRESS : SCAddrReg <= dataIn[6:0]; `SC_INTERRUPT_STATUS_REG : begin clrVBusDetReq <= dataIn[`VBUS_DET_INT_BIT]; clrNAKReq <= dataIn[`NAK_SENT_INT_BIT]; clrSOFReq <= dataIn[`SOF_RECEIVED_BIT]; clrResetReq <= dataIn[`RESET_EVENT_BIT]; clrResInReq <= dataIn[`RESUME_INT_BIT]; clrTransDoneReq <= dataIn[`TRANS_DONE_BIT]; end `SC_INTERRUPT_MASK_REG : interruptMaskReg <= dataIn[5:0]; endcase end end end //interrupt control always @(posedge busClk) begin if (rstSyncToBusClk == 1'b1) begin vBusDetInt <= 1'b0; NAKSentInt <= 1'b0; SOFRxedInt <= 1'b0; resetEventInt <= 1'b0; resumeInt <= 1'b0; transDoneInt <= 1'b0; end else begin if (vBusDetectInSTB[0] != vBusDetectInSTB[1]) vBusDetInt <= 1'b1; else if (clrVBusDetReq == 1'b1) vBusDetInt <= 1'b0; if (NAKSentInSTB[1] == 1'b1 && NAKSentInSTB[0] == 1'b0) NAKSentInt <= 1'b1; else if (clrNAKReq == 1'b1) NAKSentInt <= 1'b0; if (SOFRxedInSTB[1] == 1'b1 && SOFRxedInSTB[0] == 1'b0) SOFRxedInt <= 1'b1; else if (clrSOFReq == 1'b1) SOFRxedInt <= 1'b0; if (resetEventInSTB[1] == 1'b1 && resetEventInSTB[0] == 1'b0) resetEventInt <= 1'b1; else if (clrResetReq == 1'b1) resetEventInt <= 1'b0; if (resumeIntInSTB[1] == 1'b1 && resumeIntInSTB[0] == 1'b0) resumeInt <= 1'b1; else if (clrResInReq == 1'b1) resumeInt <= 1'b0; if (transDoneInSTB[1] == 1'b1 && transDoneInSTB[0] == 1'b0) transDoneInt <= 1'b1; else if (clrTransDoneReq == 1'b1) transDoneInt <= 1'b0; end end //mask interrupts always @(*) begin transDoneIntOut <= transDoneInt & interruptMaskReg[`TRANS_DONE_BIT]; resumeIntOut <= resumeInt & interruptMaskReg[`RESUME_INT_BIT]; resetEventIntOut <= resetEventInt & interruptMaskReg[`RESET_EVENT_BIT]; SOFRxedIntOut <= SOFRxedInt & interruptMaskReg[`SOF_RECEIVED_BIT]; NAKSentIntOut <= NAKSentInt & interruptMaskReg[`NAK_SENT_INT_BIT]; vBusDetIntOut <= vBusDetInt & interruptMaskReg[`VBUS_DET_INT_BIT]; end //end point ready, set/clear //Since 'busClk' can be a higher freq than 'usbClk', //'EP0SetReady' etc must be delayed with respect to other control signals, thus //ensuring that control signals have been clocked through to 'usbClk' clock //domain before the ready is asserted. //Not sure this is required because there is at least two 'usbClk' ticks between //detection of 'EP0Ready' and sampling of related control signals. always @(posedge busClk) begin if (rstSyncToBusClk == 1'b1) begin EP0Ready <= 1'b0; EP1Ready <= 1'b0; EP2Ready <= 1'b0; EP3Ready <= 1'b0; end else begin if (EP0SetReady == 1'b1) EP0Ready <= 1'b1; else if (clrEP0ReadySTB[1] == 1'b1 && clrEP0ReadySTB[0] == 1'b0) EP0Ready <= 1'b0; if (EP1SetReady == 1'b1) EP1Ready <= 1'b1; else if (clrEP1ReadySTB[1] == 1'b1 && clrEP1ReadySTB[0] == 1'b0) EP1Ready <= 1'b0; if (EP2SetReady == 1'b1) EP2Ready <= 1'b1; else if (clrEP2ReadySTB[1] == 1'b1 && clrEP2ReadySTB[0] == 1'b0) EP2Ready <= 1'b0; if (EP3SetReady == 1'b1) EP3Ready <= 1'b1; else if (clrEP3ReadySTB[1] == 1'b1 && clrEP3ReadySTB[0] == 1'b0) EP3Ready <= 1'b0; end end //break out control signals always @(SCControlReg) begin SCGlobalEnSTB <= SCControlReg[`SC_GLOBAL_ENABLE_BIT]; TxLineStateSTB <= SCControlReg[`SC_TX_LINE_STATE_MSBIT:`SC_TX_LINE_STATE_LSBIT]; LineDirectControlEnSTB <= SCControlReg[`SC_DIRECT_CONTROL_BIT]; fullSpeedPolSTB <= SCControlReg[`SC_FULL_SPEED_LINE_POLARITY_BIT]; fullSpeedRateSTB <= SCControlReg[`SC_FULL_SPEED_LINE_RATE_BIT]; connectSlaveToHostSTB <= SCControlReg[`SC_CONNECT_TO_HOST_BIT]; end //combine endpoint control signals always @(*) begin endP0ControlRegSTB <= {EP0IsoEn, EP0SendStall, EP0DataSequence, EP0Ready, EP0Enable}; endP1ControlRegSTB <= {EP1IsoEn, EP1SendStall, EP1DataSequence, EP1Ready, EP1Enable}; endP2ControlRegSTB <= {EP2IsoEn, EP2SendStall, EP2DataSequence, EP2Ready, EP2Enable}; endP3ControlRegSTB <= {EP3IsoEn, EP3SendStall, EP3DataSequence, EP3Ready, EP3Enable}; end // async read mux always @(*) begin case (address) `EP0_CTRL_REG : dataOut <= endP0ControlRegSTB; `EP0_STS_REG : dataOut <= EP0StatusRegSTB; `EP0_TRAN_TYPE_STS_REG : dataOut <= endP0TransTypeRegSTB; `EP0_NAK_TRAN_TYPE_STS_REG : dataOut <= endP0NAKTransTypeRegSTB; `EP1_CTRL_REG : dataOut <= endP1ControlRegSTB; `EP1_STS_REG : dataOut <= EP1StatusRegSTB; `EP1_TRAN_TYPE_STS_REG : dataOut <= endP1TransTypeRegSTB; `EP1_NAK_TRAN_TYPE_STS_REG : dataOut <= endP1NAKTransTypeRegSTB; `EP2_CTRL_REG : dataOut <= endP2ControlRegSTB; `EP2_STS_REG : dataOut <= EP2StatusRegSTB; `EP2_TRAN_TYPE_STS_REG : dataOut <= endP2TransTypeRegSTB; `EP2_NAK_TRAN_TYPE_STS_REG : dataOut <= endP2NAKTransTypeRegSTB; `EP3_CTRL_REG : dataOut <= endP3ControlRegSTB; `EP3_STS_REG : dataOut <= EP3StatusRegSTB; `EP3_TRAN_TYPE_STS_REG : dataOut <= endP3TransTypeRegSTB; `EP3_NAK_TRAN_TYPE_STS_REG : dataOut <= endP3NAKTransTypeRegSTB; `SC_CONTROL_REG : dataOut <= SCControlReg; `SC_LINE_STATUS_REG : dataOut <= {5'b00000, vBusDetectInSTB[0], connectStateInSTB}; `SC_INTERRUPT_STATUS_REG : dataOut <= {2'b00, vBusDetInt, NAKSentInt, SOFRxedInt, resetEventInt, resumeInt, transDoneInt}; `SC_INTERRUPT_MASK_REG : dataOut <= {2'b00, interruptMaskReg}; `SC_ADDRESS : dataOut <= {1'b0, SCAddrReg}; `SC_FRAME_NUM_MSP : dataOut <= {5'b00000, frameNumSTB[10:8]}; `SC_FRAME_NUM_LSP : dataOut <= frameNumSTB[7:0]; default: dataOut <= 8'h00; endcase end //Extend SOFRxedIn, resetEventIn, resumeIntIn, transDoneIn, NAKSentIn from 1 tick //pulses to 3 tick pulses always @(posedge usbClk) begin if (rstSyncToUsbClk == 1'b1) begin SOFRxedInExtend <= 3'b000; resetEventInExtend <= 3'b000; resumeIntInExtend <= 3'b000; transDoneInExtend <= 3'b000; NAKSentInExtend <= 3'b000; clrEP0ReadyExtend <= 3'b000; clrEP1ReadyExtend <= 3'b000; clrEP2ReadyExtend <= 3'b000; clrEP3ReadyExtend <= 3'b000; end else begin if (SOFRxedIn == 1'b1) SOFRxedInExtend <= 3'b111; else SOFRxedInExtend <= {1'b0, SOFRxedInExtend[2:1]}; if (resetEventIn == 1'b1) resetEventInExtend <= 3'b111; else resetEventInExtend <= {1'b0, resetEventInExtend[2:1]}; if (resumeIntIn == 1'b1) resumeIntInExtend <= 3'b111; else resumeIntInExtend <= {1'b0, resumeIntInExtend[2:1]}; if (transDoneIn == 1'b1) transDoneInExtend <= 3'b111; else transDoneInExtend <= {1'b0, transDoneInExtend[2:1]}; if (NAKSentIn == 1'b1) NAKSentInExtend <= 3'b111; else NAKSentInExtend <= {1'b0, NAKSentInExtend[2:1]}; if (clrEP0Ready == 1'b1) clrEP0ReadyExtend <= 3'b111; else clrEP0ReadyExtend <= {1'b0, clrEP0ReadyExtend[2:1]}; if (clrEP1Ready == 1'b1) clrEP1ReadyExtend <= 3'b111; else clrEP1ReadyExtend <= {1'b0, clrEP1ReadyExtend[2:1]}; if (clrEP2Ready == 1'b1) clrEP2ReadyExtend <= 3'b111; else clrEP2ReadyExtend <= {1'b0, clrEP2ReadyExtend[2:1]}; if (clrEP3Ready == 1'b1) clrEP3ReadyExtend <= 3'b111; else clrEP3ReadyExtend <= {1'b0, clrEP3ReadyExtend[2:1]}; end end //re-sync from busClk to usbClk. always @(posedge usbClk) begin if (rstSyncToUsbClk == 1'b1) begin endP0ControlReg <= {5{1'b0}}; endP0ControlReg1 <= {5{1'b0}}; endP1ControlReg <= {5{1'b0}}; endP1ControlReg1 <= {5{1'b0}}; endP2ControlReg <= {5{1'b0}}; endP2ControlReg1 <= {5{1'b0}}; endP3ControlReg <= {5{1'b0}}; endP3ControlReg1 <= {5{1'b0}}; SCGlobalEn <= 1'b0; SCGlobalEn_reg1 <= 1'b0; TxLineState <= 2'b00; TxLineState_reg1 <= 2'b00; LineDirectControlEn <= 1'b0; LineDirectControlEn_reg1 <= 1'b0; fullSpeedPol <= 1'b0; fullSpeedPol_reg1 <= 1'b0; fullSpeedRate <= 1'b0; fullSpeedRate_reg1 <= 1'b0; connectSlaveToHost <= 1'b0; connectSlaveToHost_reg1 <= 1'b0; end else begin endP0ControlReg1 <= endP0ControlRegSTB; endP0ControlReg <= endP0ControlReg1; endP1ControlReg1 <= endP1ControlRegSTB; endP1ControlReg <= endP1ControlReg1; endP2ControlReg1 <= endP2ControlRegSTB; endP2ControlReg <= endP2ControlReg1; endP3ControlReg1 <= endP3ControlRegSTB; endP3ControlReg <= endP3ControlReg1; SCGlobalEn_reg1 <= SCGlobalEnSTB; SCGlobalEn <= SCGlobalEn_reg1; TxLineState_reg1 <= TxLineStateSTB; TxLineState <= TxLineState_reg1; LineDirectControlEn_reg1 <= LineDirectControlEnSTB; LineDirectControlEn <= LineDirectControlEn_reg1; fullSpeedPol_reg1 <= fullSpeedPolSTB; fullSpeedPol <= fullSpeedPol_reg1; fullSpeedRate_reg1 <= fullSpeedRateSTB; fullSpeedRate <= fullSpeedRate_reg1; connectSlaveToHost_reg1 <= connectSlaveToHostSTB; connectSlaveToHost <= connectSlaveToHost_reg1; end end //re-sync from usbClk and async inputs to busClk. Since 'NAKSentIn', 'SOFRxedIn' etc //are only asserted for 3 usbClk ticks //busClk freq must be greater than usbClk/3 (plus some allowance for setup and hold) freq always @(posedge busClk) begin if (rstSyncToBusClk == 1'b1) begin vBusDetectInSTB <= 3'b000; NAKSentInSTB <= 3'b000; SOFRxedInSTB <= 3'b000; resetEventInSTB <= 3'b000; resumeIntInSTB <= 3'b000; transDoneInSTB <= 3'b000; clrEP0ReadySTB <= 3'b000; clrEP1ReadySTB <= 3'b000; clrEP2ReadySTB <= 3'b000; clrEP3ReadySTB <= 3'b000; EP0StatusRegSTB <= 8'h00; EP0StatusRegSTB_reg1 <= 8'h00; EP1StatusRegSTB <= 8'h00; EP1StatusRegSTB_reg1 <= 8'h00; EP2StatusRegSTB <= 8'h00; EP2StatusRegSTB_reg1 <= 8'h00; EP3StatusRegSTB <= 8'h00; EP3StatusRegSTB_reg1 <= 8'h00; endP0TransTypeRegSTB <= 2'b00; endP0TransTypeRegSTB_reg1 <= 2'b00; endP1TransTypeRegSTB <= 2'b00; endP1TransTypeRegSTB_reg1 <= 2'b00; endP2TransTypeRegSTB <= 2'b00; endP2TransTypeRegSTB_reg1 <= 2'b00; endP3TransTypeRegSTB <= 2'b00; endP3TransTypeRegSTB_reg1 <= 2'b00; endP0NAKTransTypeRegSTB <= 2'b00; endP0NAKTransTypeRegSTB_reg1 <= 2'b00; endP1NAKTransTypeRegSTB <= 2'b00; endP1NAKTransTypeRegSTB_reg1 <= 2'b00; endP2NAKTransTypeRegSTB <= 2'b00; endP2NAKTransTypeRegSTB_reg1 <= 2'b00; endP3NAKTransTypeRegSTB <= 2'b00; endP3NAKTransTypeRegSTB_reg1 <= 2'b00; frameNumSTB <= {11{1'b0}}; frameNumSTB_reg1 <= {11{1'b0}}; connectStateInSTB <= 2'b00; connectStateInSTB_reg1 <= 2'b00; end else begin vBusDetectInSTB <= {vBusDetectIn, vBusDetectInSTB[2:1]}; NAKSentInSTB <= {NAKSentInExtend[0], NAKSentInSTB[2:1]}; SOFRxedInSTB <= {SOFRxedInExtend[0], SOFRxedInSTB[2:1]}; resetEventInSTB <= {resetEventInExtend[0], resetEventInSTB[2:1]}; resumeIntInSTB <= {resumeIntInExtend[0], resumeIntInSTB[2:1]}; transDoneInSTB <= {transDoneInExtend[0], transDoneInSTB[2:1]}; clrEP0ReadySTB <= {clrEP0ReadyExtend[0], clrEP0ReadySTB[2:1]}; clrEP1ReadySTB <= {clrEP1ReadyExtend[0], clrEP1ReadySTB[2:1]}; clrEP2ReadySTB <= {clrEP2ReadyExtend[0], clrEP2ReadySTB[2:1]}; clrEP3ReadySTB <= {clrEP3ReadyExtend[0], clrEP3ReadySTB[2:1]}; EP0StatusRegSTB_reg1 <= EP0StatusReg; EP0StatusRegSTB <= EP0StatusRegSTB_reg1; EP1StatusRegSTB_reg1 <= EP1StatusReg; EP1StatusRegSTB <= EP1StatusRegSTB_reg1; EP2StatusRegSTB_reg1 <= EP2StatusReg; EP2StatusRegSTB <= EP2StatusRegSTB_reg1; EP3StatusRegSTB_reg1 <= EP3StatusReg; EP3StatusRegSTB <= EP3StatusRegSTB_reg1; endP0TransTypeRegSTB_reg1 <= endP0TransTypeReg; endP0TransTypeRegSTB <= endP0TransTypeRegSTB_reg1; endP1TransTypeRegSTB_reg1 <= endP1TransTypeReg; endP1TransTypeRegSTB <= endP1TransTypeRegSTB_reg1; endP2TransTypeRegSTB_reg1 <= endP2TransTypeReg; endP2TransTypeRegSTB <= endP2TransTypeRegSTB_reg1; endP3TransTypeRegSTB_reg1 <= endP3TransTypeReg; endP3TransTypeRegSTB <= endP3TransTypeRegSTB_reg1; endP0NAKTransTypeRegSTB_reg1 <= endP0NAKTransTypeReg; endP0NAKTransTypeRegSTB <= endP0NAKTransTypeRegSTB_reg1; endP1NAKTransTypeRegSTB_reg1 <= endP1NAKTransTypeReg; endP1NAKTransTypeRegSTB <= endP1NAKTransTypeRegSTB_reg1; endP2NAKTransTypeRegSTB_reg1 <= endP2NAKTransTypeReg; endP2NAKTransTypeRegSTB <= endP2NAKTransTypeRegSTB_reg1; endP3NAKTransTypeRegSTB_reg1 <= endP3NAKTransTypeReg; endP3NAKTransTypeRegSTB <= endP3NAKTransTypeRegSTB_reg1; frameNumSTB_reg1 <= frameNum; frameNumSTB <= frameNumSTB_reg1; connectStateInSTB_reg1 <= connectStateIn; connectStateInSTB <= connectStateInSTB_reg1; end end endmodule
Go to most recent revision | Compare with Previous | Blame | View Log