//////////////////////////////////////////////////////////////////////
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//////////////////////////////////////////////////////////////////////
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//// ////
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//// ////
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//// File name "pciw_pcir_fifos.v" ////
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//// File name "pciw_pcir_fifos.v" ////
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//// ////
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//// ////
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//// This file is part of the "PCI bridge" project ////
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//// This file is part of the "PCI bridge" project ////
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//// http://www.opencores.org/cores/pci/ ////
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//// http://www.opencores.org/cores/pci/ ////
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//// ////
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//// ////
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//// Author(s): ////
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//// Author(s): ////
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//// - Miha Dolenc (mihad@opencores.org) ////
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//// - Miha Dolenc (mihad@opencores.org) ////
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//// ////
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//// ////
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//// All additional information is avaliable in the README ////
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//// All additional information is avaliable in the README ////
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//// file. ////
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//// file. ////
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//// ////
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//// ////
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//// ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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//////////////////////////////////////////////////////////////////////
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//// ////
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//// ////
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//// Copyright (C) 2000 Miha Dolenc, mihad@opencores.org ////
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//// Copyright (C) 2000 Miha Dolenc, mihad@opencores.org ////
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//// ////
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//// ////
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//// This source file may be used and distributed without ////
|
//// This source file may be used and distributed without ////
|
//// restriction provided that this copyright statement is not ////
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//// restriction provided that this copyright statement is not ////
|
//// removed from the file and that any derivative work contains ////
|
//// removed from the file and that any derivative work contains ////
|
//// the original copyright notice and the associated disclaimer. ////
|
//// the original copyright notice and the associated disclaimer. ////
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//// ////
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//// ////
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//// This source file is free software; you can redistribute it ////
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//// This source file is free software; you can redistribute it ////
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//// and/or modify it under the terms of the GNU Lesser General ////
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//// and/or modify it under the terms of the GNU Lesser General ////
|
//// Public License as published by the Free Software Foundation; ////
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//// Public License as published by the Free Software Foundation; ////
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//// either version 2.1 of the License, or (at your option) any ////
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//// either version 2.1 of the License, or (at your option) any ////
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//// later version. ////
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//// later version. ////
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//// ////
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//// ////
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//// This source is distributed in the hope that it will be ////
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//// This source is distributed in the hope that it will be ////
|
//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
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//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
|
//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
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//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
|
//// PURPOSE. See the GNU Lesser General Public License for more ////
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//// PURPOSE. See the GNU Lesser General Public License for more ////
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//// details. ////
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//// details. ////
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//// ////
|
//// ////
|
//// You should have received a copy of the GNU Lesser General ////
|
//// You should have received a copy of the GNU Lesser General ////
|
//// Public License along with this source; if not, download it ////
|
//// Public License along with this source; if not, download it ////
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//// from http://www.opencores.org/lgpl.shtml ////
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//// from http://www.opencores.org/lgpl.shtml ////
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//// ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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//////////////////////////////////////////////////////////////////////
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//
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//
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// CVS Revision History
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// CVS Revision History
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//
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//
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// $Log: not supported by cvs2svn $
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// $Log: not supported by cvs2svn $
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// Revision 1.4 2003/08/08 16:36:33 tadejm
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|
// Added 'three_left_out' to pci_pciw_fifo signaling three locations before full. Added comparison between current registered cbe and next unregistered cbe to signal wb_master whether it is allowed to performe burst or not. Due to this, I needed 'three_left_out' so that writing to pci_pciw_fifo can be registered, otherwise timing problems would occure.
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|
//
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// Revision 1.3 2003/03/26 13:16:18 mihad
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// Revision 1.3 2003/03/26 13:16:18 mihad
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// Added the reset value parameter to the synchronizer flop module.
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// Added the reset value parameter to the synchronizer flop module.
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// Added resets to all synchronizer flop instances.
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// Added resets to all synchronizer flop instances.
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// Repaired initial sync value in fifos.
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// Repaired initial sync value in fifos.
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//
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//
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// Revision 1.2 2003/01/30 22:01:08 mihad
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// Revision 1.2 2003/01/30 22:01:08 mihad
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// Updated synchronization in top level fifo modules.
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// Updated synchronization in top level fifo modules.
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//
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//
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// Revision 1.1 2003/01/27 16:49:31 mihad
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// Revision 1.1 2003/01/27 16:49:31 mihad
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// Changed module and file names. Updated scripts accordingly. FIFO synchronizations changed.
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// Changed module and file names. Updated scripts accordingly. FIFO synchronizations changed.
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//
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//
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// Revision 1.10 2002/10/18 03:36:37 tadejm
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// Revision 1.10 2002/10/18 03:36:37 tadejm
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// Changed wrong signal name scanb_sen into scanb_en.
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// Changed wrong signal name scanb_sen into scanb_en.
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//
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//
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// Revision 1.9 2002/10/17 22:51:08 tadejm
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// Revision 1.9 2002/10/17 22:51:08 tadejm
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// Changed BIST signals for RAMs.
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// Changed BIST signals for RAMs.
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//
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//
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// Revision 1.8 2002/10/11 10:09:01 mihad
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// Revision 1.8 2002/10/11 10:09:01 mihad
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// Added additional testcase and changed rst name in BIST to trst
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// Added additional testcase and changed rst name in BIST to trst
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//
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//
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// Revision 1.7 2002/10/08 17:17:06 mihad
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// Revision 1.7 2002/10/08 17:17:06 mihad
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// Added BIST signals for RAMs.
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// Added BIST signals for RAMs.
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//
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//
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// Revision 1.6 2002/09/30 16:03:04 mihad
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// Revision 1.6 2002/09/30 16:03:04 mihad
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// Added meta flop module for easier meta stable FF identification during synthesis
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// Added meta flop module for easier meta stable FF identification during synthesis
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//
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//
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// Revision 1.5 2002/09/25 15:53:52 mihad
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// Revision 1.5 2002/09/25 15:53:52 mihad
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// Removed all logic from asynchronous reset network
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// Removed all logic from asynchronous reset network
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//
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//
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// Revision 1.4 2002/03/05 11:53:47 mihad
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// Revision 1.4 2002/03/05 11:53:47 mihad
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// Added some testcases, removed un-needed fifo signals
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// Added some testcases, removed un-needed fifo signals
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//
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//
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// Revision 1.3 2002/02/01 15:25:13 mihad
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// Revision 1.3 2002/02/01 15:25:13 mihad
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// Repaired a few bugs, updated specification, added test bench files and design document
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// Repaired a few bugs, updated specification, added test bench files and design document
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//
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//
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// Revision 1.2 2001/10/05 08:14:30 mihad
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// Revision 1.2 2001/10/05 08:14:30 mihad
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// Updated all files with inclusion of timescale file for simulation purposes.
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// Updated all files with inclusion of timescale file for simulation purposes.
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//
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//
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// Revision 1.1.1.1 2001/10/02 15:33:47 mihad
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// Revision 1.1.1.1 2001/10/02 15:33:47 mihad
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// New project directory structure
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// New project directory structure
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//
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//
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//
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//
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`include "pci_constants.v"
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`include "pci_constants.v"
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// synopsys translate_off
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// synopsys translate_off
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`include "timescale.v"
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`include "timescale.v"
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// synopsys translate_on
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// synopsys translate_on
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module pci_pciw_pcir_fifos
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module pci_pciw_pcir_fifos
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(
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(
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wb_clock_in,
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wb_clock_in,
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pci_clock_in,
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pci_clock_in,
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reset_in,
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reset_in,
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pciw_wenable_in,
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pciw_wenable_in,
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pciw_addr_data_in,
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pciw_addr_data_in,
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pciw_cbe_in,
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pciw_cbe_in,
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pciw_control_in,
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pciw_control_in,
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pciw_renable_in,
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pciw_renable_in,
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pciw_addr_data_out,
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pciw_addr_data_out,
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pciw_cbe_out,
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pciw_cbe_out,
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pciw_control_out,
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pciw_control_out,
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// pciw_flush_in, // not used
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// pciw_flush_in, // not used
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pciw_three_left_out,
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pciw_three_left_out,
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pciw_two_left_out,
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pciw_two_left_out,
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pciw_almost_full_out,
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pciw_almost_full_out,
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pciw_full_out,
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pciw_full_out,
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pciw_almost_empty_out,
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pciw_almost_empty_out,
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pciw_empty_out,
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pciw_empty_out,
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pciw_transaction_ready_out,
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pciw_transaction_ready_out,
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pcir_wenable_in,
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pcir_wenable_in,
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pcir_data_in,
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pcir_data_in,
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pcir_be_in,
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pcir_be_in,
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pcir_control_in,
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pcir_control_in,
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pcir_renable_in,
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pcir_renable_in,
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pcir_data_out,
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pcir_data_out,
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pcir_be_out,
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pcir_be_out,
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pcir_control_out,
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pcir_control_out,
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pcir_flush_in,
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pcir_flush_in,
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pcir_full_out,
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pcir_full_out,
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pcir_almost_empty_out,
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pcir_almost_empty_out,
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pcir_empty_out,
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pcir_empty_out,
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pcir_transaction_ready_out
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pcir_transaction_ready_out
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|
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`ifdef PCI_BIST
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`ifdef PCI_BIST
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,
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,
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// debug chain signals
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// debug chain signals
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scanb_rst, // bist scan reset
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scanb_rst, // bist scan reset
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scanb_clk, // bist scan clock
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scanb_clk, // bist scan clock
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scanb_si, // bist scan serial in
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scanb_si, // bist scan serial in
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scanb_so, // bist scan serial out
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scanb_so, // bist scan serial out
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scanb_en // bist scan shift enable
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scanb_en // bist scan shift enable
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`endif
|
`endif
|
) ;
|
) ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
System inputs:
|
System inputs:
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wb_clock_in - WISHBONE bus clock
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wb_clock_in - WISHBONE bus clock
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pci_clock_in - PCI bus clock
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pci_clock_in - PCI bus clock
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reset_in - reset from control logic
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reset_in - reset from control logic
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-------------------------------------------------------------------------------------------------------------*/
|
-------------------------------------------------------------------------------------------------------------*/
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input wb_clock_in, pci_clock_in, reset_in ;
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input wb_clock_in, pci_clock_in, reset_in ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
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/*-----------------------------------------------------------------------------------------------------------
|
PCI WRITE FIFO interface signals prefixed with pciw_ - FIFO is used for posted writes initiated by external
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PCI WRITE FIFO interface signals prefixed with pciw_ - FIFO is used for posted writes initiated by external
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PCI master through PCI target interface, traveling through FIFO and are completed on WISHBONE by
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PCI master through PCI target interface, traveling through FIFO and are completed on WISHBONE by
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WISHBONE master interface
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WISHBONE master interface
|
|
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write enable signal:
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write enable signal:
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pciw_wenable_in = write enable input for PCIW_FIFO - driven by PCI TARGET interface
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pciw_wenable_in = write enable input for PCIW_FIFO - driven by PCI TARGET interface
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|
|
data input signals:
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data input signals:
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pciw_addr_data_in = data input - data from PCI bus - first entry of transaction is address others are data entries
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pciw_addr_data_in = data input - data from PCI bus - first entry of transaction is address others are data entries
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pciw_cbe_in = bus command/byte enable(~#BE[3:0]) input - first entry of transaction is bus command, other are byte enables
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pciw_cbe_in = bus command/byte enable(~#BE[3:0]) input - first entry of transaction is bus command, other are byte enables
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pciw_control_in = control input - encoded control bus input
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pciw_control_in = control input - encoded control bus input
|
|
|
read enable signal:
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read enable signal:
|
pciw_renable_in = read enable input driven by WISHBONE master interface
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pciw_renable_in = read enable input driven by WISHBONE master interface
|
|
|
data output signals:
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data output signals:
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pciw_addr_data_out = data output - data from PCI bus - first entry of transaction is address, others are data entries
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pciw_addr_data_out = data output - data from PCI bus - first entry of transaction is address, others are data entries
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pciw_cbe_out = bus command/byte enable output - first entry of transaction is bus command, others are byte enables
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pciw_cbe_out = bus command/byte enable output - first entry of transaction is bus command, others are byte enables
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pciw_control_out = control input - encoded control bus input
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pciw_control_out = control input - encoded control bus input
|
|
|
status signals - monitored by various resources in the core
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status signals - monitored by various resources in the core
|
pciw_flush_in = flush signal input for PCIW_FIFO - when asserted, fifo is flushed(emptied)
|
pciw_flush_in = flush signal input for PCIW_FIFO - when asserted, fifo is flushed(emptied)
|
pciw_almost_full_out = almost full output from PCIW_FIFO
|
pciw_almost_full_out = almost full output from PCIW_FIFO
|
pciw_full_out = full output from PCIW_FIFO
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pciw_full_out = full output from PCIW_FIFO
|
pciw_almost_empty_out = almost empty output from PCIW_FIFO
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pciw_almost_empty_out = almost empty output from PCIW_FIFO
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pciw_empty_out = empty output from PCIW_FIFO
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pciw_empty_out = empty output from PCIW_FIFO
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pciw_transaction_ready_out = output indicating that one complete transaction is waiting in PCIW_FIFO
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pciw_transaction_ready_out = output indicating that one complete transaction is waiting in PCIW_FIFO
|
-----------------------------------------------------------------------------------------------------------*/
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-----------------------------------------------------------------------------------------------------------*/
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// input control and data
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// input control and data
|
input pciw_wenable_in ;
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input pciw_wenable_in ;
|
input [31:0] pciw_addr_data_in ;
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input [31:0] pciw_addr_data_in ;
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input [3:0] pciw_cbe_in ;
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input [3:0] pciw_cbe_in ;
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input [3:0] pciw_control_in ;
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input [3:0] pciw_control_in ;
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|
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// output control and data
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// output control and data
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input pciw_renable_in ;
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input pciw_renable_in ;
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output [31:0] pciw_addr_data_out ;
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output [31:0] pciw_addr_data_out ;
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output [3:0] pciw_cbe_out ;
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output [3:0] pciw_cbe_out ;
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output [3:0] pciw_control_out ;
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output [3:0] pciw_control_out ;
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|
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// flush input
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// flush input
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//input pciw_flush_in ; // not used
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//input pciw_flush_in ; // not used
|
|
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// status outputs
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// status outputs
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output pciw_three_left_out ;
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output pciw_three_left_out ;
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output pciw_two_left_out ;
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output pciw_two_left_out ;
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output pciw_almost_full_out ;
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output pciw_almost_full_out ;
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output pciw_full_out ;
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output pciw_full_out ;
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output pciw_almost_empty_out ;
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output pciw_almost_empty_out ;
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output pciw_empty_out ;
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output pciw_empty_out ;
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output pciw_transaction_ready_out ;
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output pciw_transaction_ready_out ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
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PCI READ FIFO interface signals prefixed with pcir_ - FIFO is used for holding delayed read completions
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PCI READ FIFO interface signals prefixed with pcir_ - FIFO is used for holding delayed read completions
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initiated by master on PCI bus and completed on WISHBONE bus,
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initiated by master on PCI bus and completed on WISHBONE bus,
|
|
|
write enable signal:
|
write enable signal:
|
pcir_wenable_in = write enable input for PCIR_FIFO - driven by WISHBONE master interface
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pcir_wenable_in = write enable input for PCIR_FIFO - driven by WISHBONE master interface
|
|
|
data input signals:
|
data input signals:
|
pcir_data_in = data input - data from WISHBONE bus - there is no address entry here, since address is stored in separate register
|
pcir_data_in = data input - data from WISHBONE bus - there is no address entry here, since address is stored in separate register
|
pcir_be_in = byte enable(~SEL[3:0]) input - byte enables - same through one transaction
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pcir_be_in = byte enable(~SEL[3:0]) input - byte enables - same through one transaction
|
pcir_control_in = control input - encoded control bus input
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pcir_control_in = control input - encoded control bus input
|
|
|
read enable signal:
|
read enable signal:
|
pcir_renable_in = read enable input driven by PCI target interface
|
pcir_renable_in = read enable input driven by PCI target interface
|
|
|
data output signals:
|
data output signals:
|
pcir_data_out = data output - data from WISHBONE bus
|
pcir_data_out = data output - data from WISHBONE bus
|
pcir_be_out = byte enable output(~SEL)
|
pcir_be_out = byte enable output(~SEL)
|
pcir_control_out = control output - encoded control bus output
|
pcir_control_out = control output - encoded control bus output
|
|
|
status signals - monitored by various resources in the core
|
status signals - monitored by various resources in the core
|
pcir_flush_in = flush signal input for PCIR_FIFO - when asserted, fifo is flushed(emptied)
|
pcir_flush_in = flush signal input for PCIR_FIFO - when asserted, fifo is flushed(emptied)
|
pcir full_out = full output from PCIR_FIFO
|
pcir full_out = full output from PCIR_FIFO
|
pcir_almost_empty_out = almost empty output from PCIR_FIFO
|
pcir_almost_empty_out = almost empty output from PCIR_FIFO
|
pcir_empty_out = empty output from PCIR_FIFO
|
pcir_empty_out = empty output from PCIR_FIFO
|
pcir_transaction_ready_out = output indicating that one complete transaction is waiting in PCIR_FIFO
|
pcir_transaction_ready_out = output indicating that one complete transaction is waiting in PCIR_FIFO
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
// input control and data
|
// input control and data
|
input pcir_wenable_in ;
|
input pcir_wenable_in ;
|
input [31:0] pcir_data_in ;
|
input [31:0] pcir_data_in ;
|
input [3:0] pcir_be_in ;
|
input [3:0] pcir_be_in ;
|
input [3:0] pcir_control_in ;
|
input [3:0] pcir_control_in ;
|
|
|
// output control and data
|
// output control and data
|
input pcir_renable_in ;
|
input pcir_renable_in ;
|
output [31:0] pcir_data_out ;
|
output [31:0] pcir_data_out ;
|
output [3:0] pcir_be_out ;
|
output [3:0] pcir_be_out ;
|
output [3:0] pcir_control_out ;
|
output [3:0] pcir_control_out ;
|
|
|
// flush input
|
// flush input
|
input pcir_flush_in ;
|
input pcir_flush_in ;
|
|
|
// status outputs
|
// status outputs
|
output pcir_full_out ;
|
output pcir_full_out ;
|
output pcir_almost_empty_out ;
|
output pcir_almost_empty_out ;
|
output pcir_empty_out ;
|
output pcir_empty_out ;
|
output pcir_transaction_ready_out ;
|
output pcir_transaction_ready_out ;
|
|
|
`ifdef PCI_BIST
|
`ifdef PCI_BIST
|
/*-----------------------------------------------------
|
/*-----------------------------------------------------
|
BIST debug chain port signals
|
BIST debug chain port signals
|
-----------------------------------------------------*/
|
-----------------------------------------------------*/
|
input scanb_rst; // bist scan reset
|
input scanb_rst; // bist scan reset
|
input scanb_clk; // bist scan clock
|
input scanb_clk; // bist scan clock
|
input scanb_si; // bist scan serial in
|
input scanb_si; // bist scan serial in
|
output scanb_so; // bist scan serial out
|
output scanb_so; // bist scan serial out
|
input scanb_en; // bist scan shift enable
|
input scanb_en; // bist scan shift enable
|
`endif
|
`endif
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Address length parameters:
|
Address length parameters:
|
PCIW_DEPTH = defines PCIW_FIFO depth
|
PCIW_DEPTH = defines PCIW_FIFO depth
|
PCIR_DEPTH = defines PCIR_FIFO depth
|
PCIR_DEPTH = defines PCIR_FIFO depth
|
PCIW_ADDR_LENGTH = defines PCIW_FIFO's location address length - log2(PCIW_DEPTH)
|
PCIW_ADDR_LENGTH = defines PCIW_FIFO's location address length - log2(PCIW_DEPTH)
|
PCIR_ADDR_LENGTH = defines PCIR_FIFO's location address length - log2(PCIR_DEPTH)
|
PCIR_ADDR_LENGTH = defines PCIR_FIFO's location address length - log2(PCIR_DEPTH)
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
parameter PCIW_DEPTH = `PCIW_DEPTH ;
|
parameter PCIW_DEPTH = `PCIW_DEPTH ;
|
parameter PCIW_ADDR_LENGTH = `PCIW_ADDR_LENGTH ;
|
parameter PCIW_ADDR_LENGTH = `PCIW_ADDR_LENGTH ;
|
parameter PCIR_DEPTH = `PCIR_DEPTH ;
|
parameter PCIR_DEPTH = `PCIR_DEPTH ;
|
parameter PCIR_ADDR_LENGTH = `PCIR_ADDR_LENGTH ;
|
parameter PCIR_ADDR_LENGTH = `PCIR_ADDR_LENGTH ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
pciw_wallow = PCIW_FIFO write allow wire - writes to FIFO are allowed when FIFO isn't full and write enable is 1
|
pciw_wallow = PCIW_FIFO write allow wire - writes to FIFO are allowed when FIFO isn't full and write enable is 1
|
pciw_rallow = PCIW_FIFO read allow wire - reads from FIFO are allowed when FIFO isn't empty and read enable is 1
|
pciw_rallow = PCIW_FIFO read allow wire - reads from FIFO are allowed when FIFO isn't empty and read enable is 1
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire pciw_wallow ;
|
wire pciw_wallow ;
|
wire pciw_rallow ;
|
wire pciw_rallow ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
pcir_wallow = PCIR_FIFO write allow wire - writes to FIFO are allowed when FIFO isn't full and write enable is 1
|
pcir_wallow = PCIR_FIFO write allow wire - writes to FIFO are allowed when FIFO isn't full and write enable is 1
|
pcir_rallow = PCIR_FIFO read allow wire - reads from FIFO are allowed when FIFO isn't empty and read enable is 1
|
pcir_rallow = PCIR_FIFO read allow wire - reads from FIFO are allowed when FIFO isn't empty and read enable is 1
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire pcir_wallow ;
|
wire pcir_wallow ;
|
wire pcir_rallow ;
|
wire pcir_rallow ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
wires for address port conections from PCIW_FIFO control logic to RAM blocks used for PCIW_FIFO
|
wires for address port conections from PCIW_FIFO control logic to RAM blocks used for PCIW_FIFO
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [(PCIW_ADDR_LENGTH - 1):0] pciw_raddr ;
|
wire [(PCIW_ADDR_LENGTH - 1):0] pciw_raddr ;
|
wire [(PCIW_ADDR_LENGTH - 1):0] pciw_waddr ;
|
wire [(PCIW_ADDR_LENGTH - 1):0] pciw_waddr ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
wires for address port conections from PCIR_FIFO control logic to RAM blocks used for PCIR_FIFO
|
wires for address port conections from PCIR_FIFO control logic to RAM blocks used for PCIR_FIFO
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [(PCIR_ADDR_LENGTH - 1):0] pcir_raddr ;
|
wire [(PCIR_ADDR_LENGTH - 1):0] pcir_raddr ;
|
wire [(PCIR_ADDR_LENGTH - 1):0] pcir_waddr ;
|
wire [(PCIR_ADDR_LENGTH - 1):0] pcir_waddr ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
PCIW_FIFO transaction counters: used to count incoming transactions and outgoing transactions. When number of
|
PCIW_FIFO transaction counters: used to count incoming transactions and outgoing transactions. When number of
|
input transactions is equal to number of output transactions, it means that there isn't any complete transaction
|
input transactions is equal to number of output transactions, it means that there isn't any complete transaction
|
currently present in the FIFO.
|
currently present in the FIFO.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
reg [(PCIW_ADDR_LENGTH - 1):0] pciw_inTransactionCount ;
|
reg [(PCIW_ADDR_LENGTH - 1):0] pciw_inTransactionCount ;
|
reg [(PCIW_ADDR_LENGTH - 1):0] pciw_outTransactionCount ;
|
reg [(PCIW_ADDR_LENGTH - 1):0] pciw_outTransactionCount ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
FlipFlops for indicating if complete delayed read completion is present in the FIFO
|
FlipFlops for indicating if complete delayed read completion is present in the FIFO
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
/*reg pcir_inTransactionCount ;
|
/*reg pcir_inTransactionCount ;
|
reg pcir_outTransactionCount ;*/
|
reg pcir_outTransactionCount ;*/
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
wires monitoring control bus. When control bus on a write transaction has a value of `LAST, it means that
|
wires monitoring control bus. When control bus on a write transaction has a value of `LAST, it means that
|
complete transaction is in the FIFO. When control bus on a read transaction has a value of `LAST,
|
complete transaction is in the FIFO. When control bus on a read transaction has a value of `LAST,
|
it means that there was one complete transaction taken out of FIFO.
|
it means that there was one complete transaction taken out of FIFO.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire pciw_last_in = pciw_control_in[`LAST_CTRL_BIT] ;
|
wire pciw_last_in = pciw_control_in[`LAST_CTRL_BIT] ;
|
wire pciw_last_out = pciw_control_out[`LAST_CTRL_BIT] ;
|
wire pciw_last_out = pciw_control_out[`LAST_CTRL_BIT] ;
|
|
|
/*wire pcir_last_in = pcir_wallow && (pcir_control_in == `LAST) ;
|
/*wire pcir_last_in = pcir_wallow && (pcir_control_in == `LAST) ;
|
wire pcir_last_out = pcir_rallow && (pcir_control_out == `LAST) ;*/
|
wire pcir_last_out = pcir_rallow && (pcir_control_out == `LAST) ;*/
|
|
|
wire pciw_empty ;
|
wire pciw_empty ;
|
wire pcir_empty ;
|
wire pcir_empty ;
|
|
|
assign pciw_empty_out = pciw_empty ;
|
assign pciw_empty_out = pciw_empty ;
|
assign pcir_empty_out = pcir_empty ;
|
assign pcir_empty_out = pcir_empty ;
|
|
|
// clear wires for clearing FFs and registers
|
// clear wires for clearing FFs and registers
|
wire pciw_clear = reset_in /*|| pciw_flush_in*/ ; // PCIW_FIFO's clear signal - flush not used
|
wire pciw_clear = reset_in /*|| pciw_flush_in*/ ; // PCIW_FIFO's clear signal - flush not used
|
wire pcir_clear = reset_in /*|| pcir_flush_in*/ ; // PCIR_FIFO's clear signal - flush changed to synchronous op.
|
wire pcir_clear = reset_in /*|| pcir_flush_in*/ ; // PCIR_FIFO's clear signal - flush changed to synchronous op.
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Definitions of wires for connecting RAM instances
|
Definitions of wires for connecting RAM instances
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [39:0] dpram_portA_output ;
|
wire [39:0] dpram_portA_output ;
|
wire [39:0] dpram_portB_output ;
|
wire [39:0] dpram_portB_output ;
|
|
|
wire [39:0] dpram_portA_input = {pciw_control_in, pciw_cbe_in, pciw_addr_data_in} ;
|
wire [39:0] dpram_portA_input = {pciw_control_in, pciw_cbe_in, pciw_addr_data_in} ;
|
wire [39:0] dpram_portB_input = {pcir_control_in, pcir_be_in, pcir_data_in} ;
|
wire [39:0] dpram_portB_input = {pcir_control_in, pcir_be_in, pcir_data_in} ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Fifo output assignments - each ram port provides data for different fifo
|
Fifo output assignments - each ram port provides data for different fifo
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
assign pciw_control_out = dpram_portB_output[39:36] ;
|
assign pciw_control_out = dpram_portB_output[39:36] ;
|
assign pcir_control_out = dpram_portA_output[39:36] ;
|
assign pcir_control_out = dpram_portA_output[39:36] ;
|
|
|
assign pciw_cbe_out = dpram_portB_output[35:32] ;
|
assign pciw_cbe_out = dpram_portB_output[35:32] ;
|
assign pcir_be_out = dpram_portA_output[35:32] ;
|
assign pcir_be_out = dpram_portA_output[35:32] ;
|
|
|
assign pciw_addr_data_out = dpram_portB_output[31:0] ;
|
assign pciw_addr_data_out = dpram_portB_output[31:0] ;
|
assign pcir_data_out = dpram_portA_output[31:0] ;
|
assign pcir_data_out = dpram_portA_output[31:0] ;
|
|
|
`ifdef PCI_RAM_DONT_SHARE
|
`ifdef PCI_RAM_DONT_SHARE
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Piece of code in this ifdef section is used in applications which can provide enough RAM instances to
|
Piece of code in this ifdef section is used in applications which can provide enough RAM instances to
|
accomodate four fifos - each occupying its own instance of ram. Ports are connected in such a way,
|
accomodate four fifos - each occupying its own instance of ram. Ports are connected in such a way,
|
that instances of RAMs can be changed from two port to dual port ( async read/write port ). In that case,
|
that instances of RAMs can be changed from two port to dual port ( async read/write port ). In that case,
|
write port is always port a and read port is port b.
|
write port is always port a and read port is port b.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Pad redundant address lines with zeros. This may seem stupid, but it comes in perfect for FPGA impl.
|
Pad redundant address lines with zeros. This may seem stupid, but it comes in perfect for FPGA impl.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
/*
|
/*
|
wire [(`PCIW_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH - 1):0] pciw_addr_prefix = {( `PCIW_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH){1'b0}} ;
|
wire [(`PCIW_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH - 1):0] pciw_addr_prefix = {( `PCIW_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH){1'b0}} ;
|
wire [(`PCIR_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH - 1):0] pcir_addr_prefix = {( `PCIR_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH){1'b0}} ;
|
wire [(`PCIR_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH - 1):0] pcir_addr_prefix = {( `PCIR_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH){1'b0}} ;
|
*/
|
*/
|
|
|
// compose complete port addresses
|
// compose complete port addresses
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pciw_whole_waddr = pciw_waddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pciw_whole_waddr = pciw_waddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pciw_whole_raddr = pciw_raddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pciw_whole_raddr = pciw_raddr ;
|
|
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pcir_whole_waddr = pcir_waddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pcir_whole_waddr = pcir_waddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pcir_whole_raddr = pcir_raddr ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] pcir_whole_raddr = pcir_raddr ;
|
|
|
wire pciw_read_enable = 1'b1 ;
|
wire pciw_read_enable = 1'b1 ;
|
wire pcir_read_enable = 1'b1 ;
|
wire pcir_read_enable = 1'b1 ;
|
|
|
`ifdef PCI_BIST
|
`ifdef PCI_BIST
|
wire scanb_so_internal ; // wires for connection of debug ports on two rams
|
wire scanb_so_internal ; // wires for connection of debug ports on two rams
|
wire scanb_si_internal = scanb_so_internal ;
|
wire scanb_si_internal = scanb_so_internal ;
|
`endif
|
`endif
|
|
|
// instantiate and connect two generic rams - one for pci write fifo and one for pci read fifo
|
// instantiate and connect two generic rams - one for pci write fifo and one for pci read fifo
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pciw_fifo_storage
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pciw_fifo_storage
|
(
|
(
|
// Generic synchronous two-port RAM interface
|
// Generic synchronous two-port RAM interface
|
.clk_a(pci_clock_in),
|
.clk_a(pci_clock_in),
|
.rst_a(reset_in),
|
.rst_a(reset_in),
|
.ce_a(1'b1),
|
.ce_a(1'b1),
|
.we_a(pciw_wallow),
|
.we_a(pciw_wallow),
|
.oe_a(1'b1),
|
.oe_a(1'b1),
|
.addr_a(pciw_whole_waddr),
|
.addr_a(pciw_whole_waddr),
|
.di_a(dpram_portA_input),
|
.di_a(dpram_portA_input),
|
.do_a(),
|
.do_a(),
|
|
|
.clk_b(wb_clock_in),
|
.clk_b(wb_clock_in),
|
.rst_b(reset_in),
|
.rst_b(reset_in),
|
.ce_b(pciw_read_enable),
|
.ce_b(pciw_read_enable),
|
.we_b(1'b0),
|
.we_b(1'b0),
|
.oe_b(1'b1),
|
.oe_b(1'b1),
|
.addr_b(pciw_whole_raddr),
|
.addr_b(pciw_whole_raddr),
|
.di_b(40'h00_0000_0000),
|
.di_b(40'h00_0000_0000),
|
.do_b(dpram_portB_output)
|
.do_b(dpram_portB_output)
|
|
|
`ifdef PCI_BIST
|
`ifdef PCI_BIST
|
,
|
,
|
.scanb_rst (scanb_rst),
|
.scanb_rst (scanb_rst),
|
.scanb_clk (scanb_clk),
|
.scanb_clk (scanb_clk),
|
.scanb_si (scanb_si),
|
.scanb_si (scanb_si),
|
.scanb_so (scanb_so_internal),
|
.scanb_so (scanb_so_internal),
|
.scanb_en (scanb_en)
|
.scanb_en (scanb_en)
|
`endif
|
`endif
|
);
|
);
|
|
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pcir_fifo_storage
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pcir_fifo_storage
|
(
|
(
|
// Generic synchronous two-port RAM interface
|
// Generic synchronous two-port RAM interface
|
.clk_a(wb_clock_in),
|
.clk_a(wb_clock_in),
|
.rst_a(reset_in),
|
.rst_a(reset_in),
|
.ce_a(1'b1),
|
.ce_a(1'b1),
|
.we_a(pcir_wallow),
|
.we_a(pcir_wallow),
|
.oe_a(1'b1),
|
.oe_a(1'b1),
|
.addr_a(pcir_whole_waddr),
|
.addr_a(pcir_whole_waddr),
|
.di_a(dpram_portB_input),
|
.di_a(dpram_portB_input),
|
.do_a(),
|
.do_a(),
|
|
|
.clk_b(pci_clock_in),
|
.clk_b(pci_clock_in),
|
.rst_b(reset_in),
|
.rst_b(reset_in),
|
.ce_b(pcir_read_enable),
|
.ce_b(pcir_read_enable),
|
.we_b(1'b0),
|
.we_b(1'b0),
|
.oe_b(1'b1),
|
.oe_b(1'b1),
|
.addr_b(pcir_whole_raddr),
|
.addr_b(pcir_whole_raddr),
|
.di_b(40'h00_0000_0000),
|
.di_b(40'h00_0000_0000),
|
.do_b(dpram_portA_output)
|
.do_b(dpram_portA_output)
|
|
|
`ifdef PCI_BIST
|
`ifdef PCI_BIST
|
,
|
,
|
.scanb_rst (scanb_rst),
|
.scanb_rst (scanb_rst),
|
.scanb_clk (scanb_clk),
|
.scanb_clk (scanb_clk),
|
.scanb_si (scanb_si_internal),
|
.scanb_si (scanb_si_internal),
|
.scanb_so (scanb_so),
|
.scanb_so (scanb_so),
|
.scanb_en (scanb_en)
|
.scanb_en (scanb_en)
|
`endif
|
`endif
|
);
|
);
|
|
|
`else // RAM blocks sharing between two fifos
|
`else // RAM blocks sharing between two fifos
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Code section under this ifdef is used for implementation where RAM instances are too expensive. In this
|
Code section under this ifdef is used for implementation where RAM instances are too expensive. In this
|
case one RAM instance is used for both - pci read and pci write fifo.
|
case one RAM instance is used for both - pci read and pci write fifo.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Address prefix definition - since both FIFOs reside in same RAM instance, storage is separated by MSB
|
Address prefix definition - since both FIFOs reside in same RAM instance, storage is separated by MSB
|
addresses. pci write fifo addresses are padded with zeros on the MSB side ( at least one address line
|
addresses. pci write fifo addresses are padded with zeros on the MSB side ( at least one address line
|
must be used for this ), pci read fifo addresses are padded with ones on the right ( at least one ).
|
must be used for this ), pci read fifo addresses are padded with ones on the right ( at least one ).
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH - 1):0] pciw_addr_prefix = {( `PCI_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH){1'b0}} ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH - 1):0] pciw_addr_prefix = {( `PCI_FIFO_RAM_ADDR_LENGTH - PCIW_ADDR_LENGTH){1'b0}} ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH - 1):0] pcir_addr_prefix = {( `PCI_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH){1'b1}} ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH - 1):0] pcir_addr_prefix = {( `PCI_FIFO_RAM_ADDR_LENGTH - PCIR_ADDR_LENGTH){1'b1}} ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Port A address generation for RAM instance. RAM instance must be full two port RAM - read and write capability
|
Port A address generation for RAM instance. RAM instance must be full two port RAM - read and write capability
|
on both sides.
|
on both sides.
|
Port A is clocked by PCI clock, DIA is input for pciw_fifo, DOA is output for pcir_fifo.
|
Port A is clocked by PCI clock, DIA is input for pciw_fifo, DOA is output for pcir_fifo.
|
Address is multiplexed so operation can be switched between fifos. Default is a read on port.
|
Address is multiplexed so operation can be switched between fifos. Default is a read on port.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] portA_addr = pciw_wallow ? {pciw_addr_prefix, pciw_waddr} : {pcir_addr_prefix, pcir_raddr} ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] portA_addr = pciw_wallow ? {pciw_addr_prefix, pciw_waddr} : {pcir_addr_prefix, pcir_raddr} ;
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Port B is clocked by WISHBONE clock, DIB is input for pcir_fifo, DOB is output for pciw_fifo.
|
Port B is clocked by WISHBONE clock, DIB is input for pcir_fifo, DOB is output for pciw_fifo.
|
Address is multiplexed so operation can be switched between fifos. Default is a read on port.
|
Address is multiplexed so operation can be switched between fifos. Default is a read on port.
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] portB_addr = pcir_wallow ? {pcir_addr_prefix, pcir_waddr} : {pciw_addr_prefix, pciw_raddr} ;
|
wire [(`PCI_FIFO_RAM_ADDR_LENGTH-1):0] portB_addr = pcir_wallow ? {pcir_addr_prefix, pcir_waddr} : {pciw_addr_prefix, pciw_raddr} ;
|
|
|
wire portA_enable = 1'b1 ;
|
wire portA_enable = 1'b1 ;
|
|
|
wire portB_enable = 1'b1 ;
|
wire portB_enable = 1'b1 ;
|
|
|
// instantiate RAM for these two fifos
|
// instantiate RAM for these two fifos
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pciu_fifo_storage
|
pci_pci_tpram #(`PCI_FIFO_RAM_ADDR_LENGTH, 40) pciu_fifo_storage
|
(
|
(
|
// Generic synchronous two-port RAM interface
|
// Generic synchronous two-port RAM interface
|
.clk_a(pci_clock_in),
|
.clk_a(pci_clock_in),
|
.rst_a(reset_in),
|
.rst_a(reset_in),
|
.ce_a(portA_enable),
|
.ce_a(portA_enable),
|
.we_a(pciw_wallow),
|
.we_a(pciw_wallow),
|
.oe_a(1'b1),
|
.oe_a(1'b1),
|
.addr_a(portA_addr),
|
.addr_a(portA_addr),
|
.di_a(dpram_portA_input),
|
.di_a(dpram_portA_input),
|
.do_a(dpram_portA_output),
|
.do_a(dpram_portA_output),
|
.clk_b(wb_clock_in),
|
.clk_b(wb_clock_in),
|
.rst_b(reset_in),
|
.rst_b(reset_in),
|
.ce_b(portB_enable),
|
.ce_b(portB_enable),
|
.we_b(pcir_wallow),
|
.we_b(pcir_wallow),
|
.oe_b(1'b1),
|
.oe_b(1'b1),
|
.addr_b(portB_addr),
|
.addr_b(portB_addr),
|
.di_b(dpram_portB_input),
|
.di_b(dpram_portB_input),
|
.do_b(dpram_portB_output)
|
.do_b(dpram_portB_output)
|
|
|
`ifdef PCI_BIST
|
`ifdef PCI_BIST
|
,
|
,
|
.scanb_rst (scanb_rst),
|
.scanb_rst (scanb_rst),
|
.scanb_clk (scanb_clk),
|
.scanb_clk (scanb_clk),
|
.scanb_si (scanb_si),
|
.scanb_si (scanb_si),
|
.scanb_so (scanb_so),
|
.scanb_so (scanb_so),
|
.scanb_en (scanb_en)
|
.scanb_en (scanb_en)
|
`endif
|
`endif
|
);
|
);
|
|
|
`endif
|
`endif
|
|
|
/*-----------------------------------------------------------------------------------------------------------
|
/*-----------------------------------------------------------------------------------------------------------
|
Instantiation of two control logic modules - one for PCIW_FIFO and one for PCIR_FIFO
|
Instantiation of two control logic modules - one for PCIW_FIFO and one for PCIR_FIFO
|
-----------------------------------------------------------------------------------------------------------*/
|
-----------------------------------------------------------------------------------------------------------*/
|
pci_pciw_fifo_control #(PCIW_ADDR_LENGTH) pciw_fifo_ctrl
|
pci_pciw_fifo_control #(PCIW_ADDR_LENGTH) pciw_fifo_ctrl
|
(
|
(
|
.rclock_in(wb_clock_in),
|
.rclock_in(wb_clock_in),
|
.wclock_in(pci_clock_in),
|
.wclock_in(pci_clock_in),
|
.renable_in(pciw_renable_in),
|
.renable_in(pciw_renable_in),
|
.wenable_in(pciw_wenable_in),
|
.wenable_in(pciw_wenable_in),
|
.reset_in(reset_in),
|
.reset_in(reset_in),
|
// .flush_in(pciw_flush_in), // flush not used
|
// .flush_in(pciw_flush_in), // flush not used
|
.three_left_out(pciw_three_left_out),
|
.three_left_out(pciw_three_left_out),
|
.two_left_out(pciw_two_left_out),
|
.two_left_out(pciw_two_left_out),
|
.almost_full_out(pciw_almost_full_out),
|
.almost_full_out(pciw_almost_full_out),
|
.full_out(pciw_full_out),
|
.full_out(pciw_full_out),
|
.almost_empty_out(pciw_almost_empty_out),
|
.almost_empty_out(pciw_almost_empty_out),
|
.empty_out(pciw_empty),
|
.empty_out(pciw_empty),
|
.waddr_out(pciw_waddr),
|
.waddr_out(pciw_waddr),
|
.raddr_out(pciw_raddr),
|
.raddr_out(pciw_raddr),
|
.rallow_out(pciw_rallow),
|
.rallow_out(pciw_rallow),
|
.wallow_out(pciw_wallow)
|
.wallow_out(pciw_wallow)
|
);
|
);
|
|
|
pci_pcir_fifo_control #(PCIR_ADDR_LENGTH) pcir_fifo_ctrl
|
pci_pcir_fifo_control #(PCIR_ADDR_LENGTH) pcir_fifo_ctrl
|
(
|
(
|
.rclock_in(pci_clock_in),
|
.rclock_in(pci_clock_in),
|
.wclock_in(wb_clock_in),
|
.wclock_in(wb_clock_in),
|
.renable_in(pcir_renable_in),
|
.renable_in(pcir_renable_in),
|
.wenable_in(pcir_wenable_in),
|
.wenable_in(pcir_wenable_in),
|
.reset_in(reset_in),
|
.reset_in(reset_in),
|
.flush_in(pcir_flush_in),
|
.flush_in(pcir_flush_in),
|
.full_out(pcir_full_out),
|
.full_out(pcir_full_out),
|
.almost_empty_out(pcir_almost_empty_out),
|
.almost_empty_out(pcir_almost_empty_out),
|
.empty_out(pcir_empty),
|
.empty_out(pcir_empty),
|
.waddr_out(pcir_waddr),
|
.waddr_out(pcir_waddr),
|
.raddr_out(pcir_raddr),
|
.raddr_out(pcir_raddr),
|
.rallow_out(pcir_rallow),
|
.rallow_out(pcir_rallow),
|
.wallow_out(pcir_wallow)
|
.wallow_out(pcir_wallow)
|
);
|
);
|
|
|
|
|
// in and out transaction counters and grey codes
|
// in and out transaction counters and grey codes
|
reg [(PCIW_ADDR_LENGTH-2):0] inGreyCount ;
|
reg [(PCIW_ADDR_LENGTH-2):0] inGreyCount ;
|
reg [(PCIW_ADDR_LENGTH-2):0] outGreyCount ;
|
reg [(PCIW_ADDR_LENGTH-2):0] outGreyCount ;
|
wire [(PCIW_ADDR_LENGTH-2):0] inNextGreyCount = {pciw_inTransactionCount[(PCIW_ADDR_LENGTH-2)], pciw_inTransactionCount[(PCIW_ADDR_LENGTH-2):1] ^ pciw_inTransactionCount[(PCIW_ADDR_LENGTH-3):0]} ;
|
wire [(PCIW_ADDR_LENGTH-2):0] inNextGreyCount = {pciw_inTransactionCount[(PCIW_ADDR_LENGTH-2)], pciw_inTransactionCount[(PCIW_ADDR_LENGTH-2):1] ^ pciw_inTransactionCount[(PCIW_ADDR_LENGTH-3):0]} ;
|
wire [(PCIW_ADDR_LENGTH-2):0] outNextGreyCount = {pciw_outTransactionCount[(PCIW_ADDR_LENGTH-2)], pciw_outTransactionCount[(PCIW_ADDR_LENGTH-2):1] ^ pciw_outTransactionCount[(PCIW_ADDR_LENGTH-3):0]} ;
|
wire [(PCIW_ADDR_LENGTH-2):0] outNextGreyCount = {pciw_outTransactionCount[(PCIW_ADDR_LENGTH-2)], pciw_outTransactionCount[(PCIW_ADDR_LENGTH-2):1] ^ pciw_outTransactionCount[(PCIW_ADDR_LENGTH-3):0]} ;
|
|
|
// input transaction counter is incremented when whole transaction is written to fifo. This is indicated by last control bit written to last transaction location
|
// input transaction counter is incremented when whole transaction is written to fifo. This is indicated by last control bit written to last transaction location
|
wire in_count_en = pciw_wallow && pciw_last_in ;
|
wire in_count_en = pciw_wallow && pciw_last_in ;
|
|
|
// output transaction counter is incremented when whole transaction is pulled out of fifo. This is indicated when location with last control bit set is read
|
// output transaction counter is incremented when whole transaction is pulled out of fifo. This is indicated when location with last control bit set is read
|
wire out_count_en = pciw_rallow && pciw_last_out ;
|
wire out_count_en = pciw_rallow && pciw_last_out ;
|
|
|
always@(posedge pci_clock_in or posedge pciw_clear)
|
always@(posedge pci_clock_in or posedge pciw_clear)
|
begin
|
begin
|
if (pciw_clear)
|
if (pciw_clear)
|
begin
|
begin
|
inGreyCount <= 0 ;
|
inGreyCount <= 0 ;
|
end
|
end
|
else
|
else
|
if (in_count_en)
|
if (in_count_en)
|
inGreyCount <= #`FF_DELAY inNextGreyCount ;
|
inGreyCount <= #`FF_DELAY inNextGreyCount ;
|
end
|
end
|
|
|
wire [(PCIW_ADDR_LENGTH-2):0] wb_clk_sync_inGreyCount ;
|
wire [(PCIW_ADDR_LENGTH-2):0] wb_clk_sync_inGreyCount ;
|
reg [(PCIW_ADDR_LENGTH-2):0] wb_clk_inGreyCount ;
|
reg [(PCIW_ADDR_LENGTH-2):0] wb_clk_inGreyCount ;
|
synchronizer_flop #((PCIW_ADDR_LENGTH - 1), 0) i_synchronizer_reg_inGreyCount
|
pci_synchronizer_flop #((PCIW_ADDR_LENGTH - 1), 0) i_synchronizer_reg_inGreyCount
|
(
|
(
|
.data_in (inGreyCount),
|
.data_in (inGreyCount),
|
.clk_out (wb_clock_in),
|
.clk_out (wb_clock_in),
|
.sync_data_out (wb_clk_sync_inGreyCount),
|
.sync_data_out (wb_clk_sync_inGreyCount),
|
.async_reset (pciw_clear)
|
.async_reset (pciw_clear)
|
) ;
|
) ;
|
|
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
begin
|
begin
|
if (pciw_clear)
|
if (pciw_clear)
|
wb_clk_inGreyCount <= #`FF_DELAY 0 ;
|
wb_clk_inGreyCount <= #`FF_DELAY 0 ;
|
else
|
else
|
wb_clk_inGreyCount <= # `FF_DELAY wb_clk_sync_inGreyCount ;
|
wb_clk_inGreyCount <= # `FF_DELAY wb_clk_sync_inGreyCount ;
|
end
|
end
|
|
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
begin
|
begin
|
if (pciw_clear)
|
if (pciw_clear)
|
begin
|
begin
|
outGreyCount <= #`FF_DELAY 0 ;
|
outGreyCount <= #`FF_DELAY 0 ;
|
end
|
end
|
else
|
else
|
if (out_count_en)
|
if (out_count_en)
|
outGreyCount <= #`FF_DELAY outNextGreyCount ;
|
outGreyCount <= #`FF_DELAY outNextGreyCount ;
|
end
|
end
|
|
|
always@(posedge pci_clock_in or posedge pciw_clear)
|
always@(posedge pci_clock_in or posedge pciw_clear)
|
begin
|
begin
|
if (pciw_clear)
|
if (pciw_clear)
|
pciw_inTransactionCount <= #`FF_DELAY 1 ;
|
pciw_inTransactionCount <= #`FF_DELAY 1 ;
|
else
|
else
|
if (in_count_en)
|
if (in_count_en)
|
pciw_inTransactionCount <= #`FF_DELAY pciw_inTransactionCount + 1'b1 ;
|
pciw_inTransactionCount <= #`FF_DELAY pciw_inTransactionCount + 1'b1 ;
|
end
|
end
|
|
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
always@(posedge wb_clock_in or posedge pciw_clear)
|
begin
|
begin
|
if (pciw_clear)
|
if (pciw_clear)
|
pciw_outTransactionCount <= #`FF_DELAY 1 ;
|
pciw_outTransactionCount <= #`FF_DELAY 1 ;
|
else
|
else
|
if (out_count_en)
|
if (out_count_en)
|
pciw_outTransactionCount <= #`FF_DELAY pciw_outTransactionCount + 1'b1 ;
|
pciw_outTransactionCount <= #`FF_DELAY pciw_outTransactionCount + 1'b1 ;
|
end
|
end
|
|
|
assign pciw_transaction_ready_out = wb_clk_inGreyCount != outGreyCount ;
|
assign pciw_transaction_ready_out = wb_clk_inGreyCount != outGreyCount ;
|
|
|
assign pcir_transaction_ready_out = 1'b0 ;
|
assign pcir_transaction_ready_out = 1'b0 ;
|
|
|
endmodule
|
endmodule
|
|
|
|
|