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[/] [openrisc/] [trunk/] [or1200/] [rtl/] [verilog/] [or1200_rfram_generic.v] - Rev 855
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////////////////////////////////////////////////////////////////////// //// //// //// OR1200's register file generic memory //// //// //// //// This file is part of the OpenRISC 1200 project //// //// http://www.opencores.org/cores/or1k/ //// //// //// //// Description //// //// Generic (flip-flop based) register file memory //// //// //// //// To Do: //// //// - nothing //// //// //// //// 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_rfram_generic.v,v $ // Revision 2.0 2010/06/30 11:00:00 ORSoC // Minor update: // Defines added, coding style changed. // // Revision 1.3 2004/06/08 18:16:32 lampret // GPR0 hardwired to zero. // // Revision 1.2 2002/09/03 22:28:21 lampret // As per Taylor Su suggestion all case blocks are full case by default and optionally (OR1200_CASE_DEFAULT) can be disabled to increase clock frequncy. // // Revision 1.1 2002/06/08 16:23:30 lampret // Generic flip-flop based memory macro for register file. // // // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "or1200_defines.v" module or1200_rfram_generic( // Clock and reset clk, rst, // Port A ce_a, addr_a, do_a, // Port B ce_b, addr_b, do_b, // Port W ce_w, we_w, addr_w, di_w ); parameter dw = `OR1200_OPERAND_WIDTH; parameter aw = `OR1200_REGFILE_ADDR_WIDTH; // // I/O // // // Clock and reset // input clk; input rst; // // Port A // input ce_a; input [aw-1:0] addr_a; output [dw-1:0] do_a; // // Port B // input ce_b; input [aw-1:0] addr_b; output [dw-1:0] do_b; // // Port W // input ce_w; input we_w; input [aw-1:0] addr_w; input [dw-1:0] di_w; // // Internal wires and regs // reg [aw-1:0] intaddr_a; reg [aw-1:0] intaddr_b; `ifdef OR1200_RFRAM_16REG reg [16*dw-1:0] mem; `else reg [32*dw-1:0] mem; `endif reg [dw-1:0] do_a; reg [dw-1:0] do_b; `ifdef verilator // Function to access GPRs (for use by Verilator). No need to hide this one // from the simulator, since it has an input (as required by IEEE 1364-2001). function [31:0] get_gpr; // verilator public input [aw-1:0] gpr_no; get_gpr = { mem[gpr_no*32 + 31], mem[gpr_no*32 + 30], mem[gpr_no*32 + 29], mem[gpr_no*32 + 28], mem[gpr_no*32 + 27], mem[gpr_no*32 + 26], mem[gpr_no*32 + 25], mem[gpr_no*32 + 24], mem[gpr_no*32 + 23], mem[gpr_no*32 + 22], mem[gpr_no*32 + 21], mem[gpr_no*32 + 20], mem[gpr_no*32 + 19], mem[gpr_no*32 + 18], mem[gpr_no*32 + 17], mem[gpr_no*32 + 16], mem[gpr_no*32 + 15], mem[gpr_no*32 + 14], mem[gpr_no*32 + 13], mem[gpr_no*32 + 12], mem[gpr_no*32 + 11], mem[gpr_no*32 + 10], mem[gpr_no*32 + 9], mem[gpr_no*32 + 8], mem[gpr_no*32 + 7], mem[gpr_no*32 + 6], mem[gpr_no*32 + 5], mem[gpr_no*32 + 4], mem[gpr_no*32 + 3], mem[gpr_no*32 + 2], mem[gpr_no*32 + 1], mem[gpr_no*32 + 0] }; endfunction // get_gpr // Function to access GPRs (for use by Verilator). No need to hide this one // from the simulator, since it has an input (as required by IEEE 1364-2001). function [31:0] set_gpr; // verilator public input [aw-1:0] gpr_no; input [dw-1:0] value; mem[gpr_no*32 + 31] = value[31]; mem[gpr_no*32 + 30] = value[30]; mem[gpr_no*32 + 29] = value[29]; mem[gpr_no*32 + 28] = value[28]; mem[gpr_no*32 + 27] = value[27]; mem[gpr_no*32 + 26] = value[26]; mem[gpr_no*32 + 25] = value[25]; mem[gpr_no*32 + 24] = value[24]; mem[gpr_no*32 + 23] = value[23]; mem[gpr_no*32 + 22] = value[22]; mem[gpr_no*32 + 21] = value[21]; mem[gpr_no*32 + 20] = value[20]; mem[gpr_no*32 + 19] = value[19]; mem[gpr_no*32 + 18] = value[18]; mem[gpr_no*32 + 17] = value[17]; mem[gpr_no*32 + 16] = value[16]; mem[gpr_no*32 + 15] = value[15]; mem[gpr_no*32 + 14] = value[14]; mem[gpr_no*32 + 13] = value[13]; mem[gpr_no*32 + 12] = value[12]; mem[gpr_no*32 + 11] = value[11]; mem[gpr_no*32 + 10] = value[10]; mem[gpr_no*32 + 9] = value[ 9]; mem[gpr_no*32 + 8] = value[ 8]; mem[gpr_no*32 + 7] = value[ 7]; mem[gpr_no*32 + 6] = value[ 6]; mem[gpr_no*32 + 5] = value[ 5]; mem[gpr_no*32 + 4] = value[ 4]; mem[gpr_no*32 + 3] = value[ 3]; mem[gpr_no*32 + 2] = value[ 2]; mem[gpr_no*32 + 1] = value[ 1]; mem[gpr_no*32 + 0] = value[ 0]; set_gpr = 0; endfunction // set_gpr `endif // `ifdef verilator // // Write port // always @(posedge clk or `OR1200_RST_EVENT rst) if (rst == `OR1200_RST_VALUE) begin mem <= {512'h0, 512'h0}; end else if (ce_w & we_w) case (addr_w) // synopsys parallel_case 5'd01: mem[32*1+31:32*1] <= di_w; 5'd02: mem[32*2+31:32*2] <= di_w; 5'd03: mem[32*3+31:32*3] <= di_w; 5'd04: mem[32*4+31:32*4] <= di_w; 5'd05: mem[32*5+31:32*5] <= di_w; 5'd06: mem[32*6+31:32*6] <= di_w; 5'd07: mem[32*7+31:32*7] <= di_w; 5'd08: mem[32*8+31:32*8] <= di_w; 5'd09: mem[32*9+31:32*9] <= di_w; 5'd10: mem[32*10+31:32*10] <= di_w; 5'd11: mem[32*11+31:32*11] <= di_w; 5'd12: mem[32*12+31:32*12] <= di_w; 5'd13: mem[32*13+31:32*13] <= di_w; 5'd14: mem[32*14+31:32*14] <= di_w; 5'd15: mem[32*15+31:32*15] <= di_w; `ifdef OR1200_RFRAM_16REG `else 5'd16: mem[32*16+31:32*16] <= di_w; 5'd17: mem[32*17+31:32*17] <= di_w; 5'd18: mem[32*18+31:32*18] <= di_w; 5'd19: mem[32*19+31:32*19] <= di_w; 5'd20: mem[32*20+31:32*20] <= di_w; 5'd21: mem[32*21+31:32*21] <= di_w; 5'd22: mem[32*22+31:32*22] <= di_w; 5'd23: mem[32*23+31:32*23] <= di_w; 5'd24: mem[32*24+31:32*24] <= di_w; 5'd25: mem[32*25+31:32*25] <= di_w; 5'd26: mem[32*26+31:32*26] <= di_w; 5'd27: mem[32*27+31:32*27] <= di_w; 5'd28: mem[32*28+31:32*28] <= di_w; 5'd29: mem[32*29+31:32*29] <= di_w; 5'd30: mem[32*30+31:32*30] <= di_w; 5'd31: mem[32*31+31:32*31] <= di_w; `endif default: mem[32*0+31:32*0] <= 32'h0000_0000; endcase // // Read port A // always @(posedge clk or `OR1200_RST_EVENT rst) if (rst == `OR1200_RST_VALUE) begin intaddr_a <= 5'h00; end else if (ce_a) intaddr_a <= addr_a; always @(mem or intaddr_a) case (intaddr_a) // synopsys parallel_case 5'd01: do_a = mem[32*1+31:32*1]; 5'd02: do_a = mem[32*2+31:32*2]; 5'd03: do_a = mem[32*3+31:32*3]; 5'd04: do_a = mem[32*4+31:32*4]; 5'd05: do_a = mem[32*5+31:32*5]; 5'd06: do_a = mem[32*6+31:32*6]; 5'd07: do_a = mem[32*7+31:32*7]; 5'd08: do_a = mem[32*8+31:32*8]; 5'd09: do_a = mem[32*9+31:32*9]; 5'd10: do_a = mem[32*10+31:32*10]; 5'd11: do_a = mem[32*11+31:32*11]; 5'd12: do_a = mem[32*12+31:32*12]; 5'd13: do_a = mem[32*13+31:32*13]; 5'd14: do_a = mem[32*14+31:32*14]; 5'd15: do_a = mem[32*15+31:32*15]; `ifdef OR1200_RFRAM_16REG `else 5'd16: do_a = mem[32*16+31:32*16]; 5'd17: do_a = mem[32*17+31:32*17]; 5'd18: do_a = mem[32*18+31:32*18]; 5'd19: do_a = mem[32*19+31:32*19]; 5'd20: do_a = mem[32*20+31:32*20]; 5'd21: do_a = mem[32*21+31:32*21]; 5'd22: do_a = mem[32*22+31:32*22]; 5'd23: do_a = mem[32*23+31:32*23]; 5'd24: do_a = mem[32*24+31:32*24]; 5'd25: do_a = mem[32*25+31:32*25]; 5'd26: do_a = mem[32*26+31:32*26]; 5'd27: do_a = mem[32*27+31:32*27]; 5'd28: do_a = mem[32*28+31:32*28]; 5'd29: do_a = mem[32*29+31:32*29]; 5'd30: do_a = mem[32*30+31:32*30]; 5'd31: do_a = mem[32*31+31:32*31]; `endif default: do_a = 32'h0000_0000; endcase // // Read port B // always @(posedge clk or `OR1200_RST_EVENT rst) if (rst == `OR1200_RST_VALUE) begin intaddr_b <= 5'h00; end else if (ce_b) intaddr_b <= addr_b; always @(mem or intaddr_b) case (intaddr_b) // synopsys parallel_case 5'd01: do_b = mem[32*1+31:32*1]; 5'd02: do_b = mem[32*2+31:32*2]; 5'd03: do_b = mem[32*3+31:32*3]; 5'd04: do_b = mem[32*4+31:32*4]; 5'd05: do_b = mem[32*5+31:32*5]; 5'd06: do_b = mem[32*6+31:32*6]; 5'd07: do_b = mem[32*7+31:32*7]; 5'd08: do_b = mem[32*8+31:32*8]; 5'd09: do_b = mem[32*9+31:32*9]; 5'd10: do_b = mem[32*10+31:32*10]; 5'd11: do_b = mem[32*11+31:32*11]; 5'd12: do_b = mem[32*12+31:32*12]; 5'd13: do_b = mem[32*13+31:32*13]; 5'd14: do_b = mem[32*14+31:32*14]; 5'd15: do_b = mem[32*15+31:32*15]; `ifdef OR1200_RFRAM_16REG `else 5'd16: do_b = mem[32*16+31:32*16]; 5'd17: do_b = mem[32*17+31:32*17]; 5'd18: do_b = mem[32*18+31:32*18]; 5'd19: do_b = mem[32*19+31:32*19]; 5'd20: do_b = mem[32*20+31:32*20]; 5'd21: do_b = mem[32*21+31:32*21]; 5'd22: do_b = mem[32*22+31:32*22]; 5'd23: do_b = mem[32*23+31:32*23]; 5'd24: do_b = mem[32*24+31:32*24]; 5'd25: do_b = mem[32*25+31:32*25]; 5'd26: do_b = mem[32*26+31:32*26]; 5'd27: do_b = mem[32*27+31:32*27]; 5'd28: do_b = mem[32*28+31:32*28]; 5'd29: do_b = mem[32*29+31:32*29]; 5'd30: do_b = mem[32*30+31:32*30]; 5'd31: do_b = mem[32*31+31:32*31]; `endif default: do_b = 32'h0000_0000; endcase endmodule
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