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[/] [openrisc/] [trunk/] [or1200/] [rtl/] [verilog/] [or1200_xcv_ram32x8d.v] - Rev 848
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////////////////////////////////////////////////////////////////////// //// //// //// Xilinx Virtex RAM 32x8D //// //// //// //// This file is part of the OpenRISC 1200 project //// //// http://www.opencores.org/cores/or1k/ //// //// //// //// Description //// //// Virtex dual-port memory //// //// //// //// To Do: //// //// - make it smaller and faster //// //// //// //// Author(s): //// //// - Damjan Lampret, lampret@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// // // CVS Revision History // // $Log: or1200_xcv_ram32x8d.v,v $ // Revision 2.0 2010/06/30 11:00:00 ORSoC // No update // // Revision 1.2 2002/07/14 22:17:17 lampret // Added simple trace buffer [only for Xilinx Virtex target]. Fixed instruction fetch abort when new exception is recognized. // // Revision 1.1 2002/01/03 08:16:15 lampret // New prefixes for RTL files, prefixed module names. Updated cache controllers and MMUs. // // Revision 1.7 2001/10/21 17:57:16 lampret // Removed params from generic_XX.v. Added translate_off/on in sprs.v and id.v. Removed spr_addr from dc.v and ic.v. Fixed CR+LF. // // Revision 1.6 2001/10/14 13:12:10 lampret // MP3 version. // // Revision 1.1.1.1 2001/10/06 10:18:36 igorm // no message // // Revision 1.1 2001/08/09 13:39:33 lampret // Major clean-up. // // // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "or1200_defines.v" `ifdef OR1200_XILINX_RAM32X1D `ifdef OR1200_USE_RAM16X1D_FOR_RAM32X1D module or1200_xcv_ram32x8d ( DPO, SPO, A, D, DPRA, WCLK, WE ); output [7:0] DPO; output [7:0] SPO; input [4:0] A; input [4:0] DPRA; input [7:0] D; input WCLK; input WE; wire [7:0] DPO_0; wire [7:0] SPO_0; wire [7:0] DPO_1; wire [7:0] SPO_1; wire WE_0 ; wire WE_1 ; assign DPO = DPRA[4] ? DPO_1 : DPO_0 ; assign SPO = A[4] ? SPO_1 : SPO_0 ; assign WE_0 = !A[4] && WE ; assign WE_1 = A[4] && WE ; RAM16X1D ram32x1d_0_0( .DPO(DPO_0[0]), .SPO(SPO_0[0]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[0]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 1 // RAM16X1D ram32x1d_0_1( .DPO(DPO_0[1]), .SPO(SPO_0[1]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[1]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 2 // RAM16X1D ram32x1d_0_2( .DPO(DPO_0[2]), .SPO(SPO_0[2]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[2]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 3 // RAM16X1D ram32x1d_0_3( .DPO(DPO_0[3]), .SPO(SPO_0[3]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[3]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 4 // RAM16X1D ram32x1d_0_4( .DPO(DPO_0[4]), .SPO(SPO_0[4]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[4]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 5 // RAM16X1D ram32x1d_0_5( .DPO(DPO_0[5]), .SPO(SPO_0[5]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[5]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 6 // RAM16X1D ram32x1d_0_6( .DPO(DPO_0[6]), .SPO(SPO_0[6]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[6]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); // // Instantiation of block 7 // RAM16X1D ram32x1d_0_7( .DPO(DPO_0[7]), .SPO(SPO_0[7]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[7]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_0) ); RAM16X1D ram32x1d_1_0( .DPO(DPO_1[0]), .SPO(SPO_1[0]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[0]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 1 // RAM16X1D ram32x1d_1_1( .DPO(DPO_1[1]), .SPO(SPO_1[1]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[1]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 2 // RAM16X1D ram32x1d_1_2( .DPO(DPO_1[2]), .SPO(SPO_1[2]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[2]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 3 // RAM16X1D ram32x1d_1_3( .DPO(DPO_1[3]), .SPO(SPO_1[3]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[3]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 4 // RAM16X1D ram32x1d_1_4( .DPO(DPO_1[4]), .SPO(SPO_1[4]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[4]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 5 // RAM16X1D ram32x1d_1_5( .DPO(DPO_1[5]), .SPO(SPO_1[5]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[5]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 6 // RAM16X1D ram32x1d_1_6( .DPO(DPO_1[6]), .SPO(SPO_1[6]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[6]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); // // Instantiation of block 7 // RAM16X1D ram32x1d_1_7( .DPO(DPO_1[7]), .SPO(SPO_1[7]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .D(D[7]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .WCLK(WCLK), .WE(WE_1) ); endmodule `else module or1200_xcv_ram32x8d (DPO, SPO, A, D, DPRA, WCLK, WE); // // I/O // output [7:0] DPO; output [7:0] SPO; input [4:0] A; input [4:0] DPRA; input [7:0] D; input WCLK; input WE; // // Instantiation of block 0 // RAM32X1D ram32x1d_0( .DPO(DPO[0]), .SPO(SPO[0]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[0]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 1 // RAM32X1D ram32x1d_1( .DPO(DPO[1]), .SPO(SPO[1]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[1]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 2 // RAM32X1D ram32x1d_2( .DPO(DPO[2]), .SPO(SPO[2]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[2]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 3 // RAM32X1D ram32x1d_3( .DPO(DPO[3]), .SPO(SPO[3]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[3]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 4 // RAM32X1D ram32x1d_4( .DPO(DPO[4]), .SPO(SPO[4]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[4]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 5 // RAM32X1D ram32x1d_5( .DPO(DPO[5]), .SPO(SPO[5]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[5]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 6 // RAM32X1D ram32x1d_6( .DPO(DPO[6]), .SPO(SPO[6]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[6]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); // // Instantiation of block 7 // RAM32X1D ram32x1d_7( .DPO(DPO[7]), .SPO(SPO[7]), .A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .A4(A[4]), .D(D[7]), .DPRA0(DPRA[0]), .DPRA1(DPRA[1]), .DPRA2(DPRA[2]), .DPRA3(DPRA[3]), .DPRA4(DPRA[4]), .WCLK(WCLK), .WE(WE) ); endmodule `endif `endif
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