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//////////////////////////////////////////////////////////////////////
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//// ////
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//// OR1200's register file inside CPU ////
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//// ////
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//// This file is part of the OpenRISC 1200 project ////
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//// http://www.opencores.org/project,or1k ////
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//// ////
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//// Description ////
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//// Instantiation of register file memories ////
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//// ////
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//// To Do: ////
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//// - make it smaller and faster ////
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//// ////
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//// Author(s): ////
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//// - Damjan Lampret, lampret@opencores.org ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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//// ////
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//// Copyright (C) 2000 Authors and OPENCORES.ORG ////
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//// ////
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//// This source file may be used and distributed without ////
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//// restriction provided that this copyright statement is not ////
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//// removed from the file and that any derivative work contains ////
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//// the original copyright notice and the associated disclaimer. ////
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//// ////
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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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//// 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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//// later version. ////
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//// ////
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//// This source is distributed in the hope that it will be ////
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//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
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//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
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//// PURPOSE. See the GNU Lesser General Public License for more ////
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//// details. ////
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//// ////
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//// You should have received a copy of the GNU Lesser General ////
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//// 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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//// ////
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//////////////////////////////////////////////////////////////////////
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//
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// $Log: or1200_rf.v,v $
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// Revision 2.0 2010/06/30 11:00:00 ORSoC
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// Minor update:
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// Bugs fixed, coding style changed.
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//
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// synopsys translate_off
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`include "timescale.v"
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// synopsys translate_on
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`include "or1200_defines.v"
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module or1200_rf(
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// Clock and reset
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clk, rst,
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// Write i/f
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cy_we_i, cy_we_o, supv, wb_freeze, addrw, dataw, we, flushpipe,
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// Read i/f
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id_freeze, addra, addrb, dataa, datab, rda, rdb,
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// Debug
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spr_cs, spr_write, spr_addr, spr_dat_i, spr_dat_o, du_read
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);
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parameter dw = `OR1200_OPERAND_WIDTH;
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parameter aw = `OR1200_REGFILE_ADDR_WIDTH;
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//
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// I/O
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//
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//
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// Clock and reset
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//
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input clk;
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input rst;
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//
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// Write i/f
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//
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input cy_we_i;
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output cy_we_o;
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input supv;
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input wb_freeze;
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input [aw-1:0] addrw;
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input [dw-1:0] dataw;
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input we;
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input flushpipe;
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//
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// Read i/f
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//
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input id_freeze;
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input [aw-1:0] addra;
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input [aw-1:0] addrb;
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output [dw-1:0] dataa;
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output [dw-1:0] datab;
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input rda;
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input rdb;
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//
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// SPR access for debugging purposes
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//
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input spr_cs;
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input spr_write;
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input [31:0] spr_addr;
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input [31:0] spr_dat_i;
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output [31:0] spr_dat_o;
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input du_read;
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//
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// Internal wires and regs
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//
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wire [dw-1:0] from_rfa;
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wire [dw-1:0] from_rfb;
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wire [aw-1:0] rf_addra;
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wire [aw-1:0] rf_addrw;
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wire [dw-1:0] rf_dataw;
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wire rf_we;
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wire spr_valid;
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wire rf_ena;
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wire rf_enb;
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reg rf_we_allow;
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// Logic to restore output on RFA after debug unit has read out via SPR if.
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// Problem was that the incorrect output would be on RFA after debug unit
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// had read out - this is bad if that output is relied upon by execute
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// stage for next instruction. We simply save the last address for rf A and
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// and re-read it whenever the SPR select goes low, so we must remember
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// the last address and generate a signal for falling edge of SPR cs.
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// -- Julius
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// Detect falling edge of SPR select
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reg spr_du_cs;
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wire spr_cs_fe;
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// Track RF A's address each time it's enabled
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reg [aw-1:0] addra_last;
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always @(posedge clk)
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if (rf_ena & !(spr_cs_fe | (du_read & spr_cs)))
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addra_last <= addra;
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always @(posedge clk)
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spr_du_cs <= spr_cs & du_read;
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assign spr_cs_fe = spr_du_cs & !(spr_cs & du_read);
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//
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// SPR access is valid when spr_cs is asserted and
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// SPR address matches GPR addresses
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//
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assign spr_valid = spr_cs & (spr_addr[10:5] == `OR1200_SPR_RF);
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//
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// SPR data output is always from RF A
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//
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assign spr_dat_o = from_rfa;
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//
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// Operand A comes from RF or from saved A register
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//
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assign dataa = from_rfa;
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//
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// Operand B comes from RF or from saved B register
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//
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assign datab = from_rfb;
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//
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// RF A read address is either from SPRS or normal from CPU control
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//
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assign rf_addra = (spr_valid & !spr_write) ? spr_addr[4:0] :
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spr_cs_fe ? addra_last : addra;
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//
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// RF write address is either from SPRS or normal from CPU control
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//
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assign rf_addrw = (spr_valid & spr_write) ? spr_addr[4:0] : addrw;
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//
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// RF write data is either from SPRS or normal from CPU datapath
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//
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assign rf_dataw = (spr_valid & spr_write) ? spr_dat_i : dataw;
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//
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// RF write enable is either from SPRS or normal from CPU control
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//
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always @(`OR1200_RST_EVENT rst or posedge clk)
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if (rst == `OR1200_RST_VALUE)
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rf_we_allow <= 1'b1;
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else if (~wb_freeze)
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rf_we_allow <= ~flushpipe;
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//assign rf_we = ((spr_valid & spr_write) | (we & ~wb_freeze)) & rf_we_allow & (supv | (|rf_addrw));
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assign rf_we = ((spr_valid & spr_write) | (we & ~wb_freeze)) & rf_we_allow;
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//assign cy_we_o = cy_we_i && rf_we;
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assign cy_we_o = cy_we_i && ~wb_freeze && rf_we_allow;
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//
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// CS RF A asserted when instruction reads operand A and ID stage
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// is not stalled
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//
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//assign rf_ena = rda & ~id_freeze | spr_valid; // probably works with fixed binutils
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assign rf_ena = (rda & ~id_freeze) | (spr_valid & !spr_write) | spr_cs_fe; // probably works with fixed binutils
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// assign rf_ena = 1'b1; // does not work with single-stepping
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//assign rf_ena = ~id_freeze | spr_valid; // works with broken binutils
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//
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// CS RF B asserted when instruction reads operand B and ID stage
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// is not stalled
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//
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//assign rf_enb = rdb & ~id_freeze | spr_valid;
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assign rf_enb = rdb & ~id_freeze;
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// assign rf_enb = 1'b1;
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//assign rf_enb = ~id_freeze | spr_valid; // works with broken binutils
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`ifdef OR1200_RFRAM_TWOPORT
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//
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// Instantiation of register file two-port RAM A
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//
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or1200_tpram_32x32 rf_a(
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// Port A
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.clk_a(clk),
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.rst_a(rst),
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.ce_a(rf_ena),
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.we_a(1'b0),
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.oe_a(1'b1),
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.addr_a(rf_addra),
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.di_a(32'h0000_0000),
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.do_a(from_rfa),
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// Port B
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.clk_b(clk),
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.rst_b(rst),
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.ce_b(rf_we),
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.we_b(rf_we),
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.oe_b(1'b0),
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.addr_b(rf_addrw),
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.di_b(rf_dataw),
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.do_b()
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);
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//
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// Instantiation of register file two-port RAM B
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//
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or1200_tpram_32x32 rf_b(
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// Port A
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.clk_a(clk),
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.rst_a(rst),
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.ce_a(rf_enb),
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.we_a(1'b0),
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.oe_a(1'b1),
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.addr_a(addrb),
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.di_a(32'h0000_0000),
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.do_a(from_rfb),
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// Port B
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.clk_b(clk),
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.rst_b(rst),
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.ce_b(rf_we),
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.we_b(rf_we),
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.oe_b(1'b0),
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.addr_b(rf_addrw),
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.di_b(rf_dataw),
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.do_b()
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);
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`else
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`ifdef OR1200_RFRAM_DUALPORT
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//
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// Instantiation of register file two-port RAM A
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//
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or1200_dpram #
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(
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.aw(5),
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.dw(32)
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)
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rf_a
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(
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// Port A
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.clk_a(clk),
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.ce_a(rf_ena),
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.addr_a(rf_addra),
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.do_a(from_rfa),
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// Port B
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.clk_b(clk),
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.ce_b(rf_we),
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.we_b(rf_we),
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.addr_b(rf_addrw),
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.di_b(rf_dataw)
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);
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//
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// Instantiation of register file two-port RAM B
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//
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or1200_dpram #
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(
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.aw(5),
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.dw(32)
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)
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rf_b
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(
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// Port A
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.clk_a(clk),
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.ce_a(rf_enb),
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.addr_a(addrb),
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.do_a(from_rfb),
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// Port B
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.clk_b(clk),
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.ce_b(rf_we),
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.we_b(rf_we),
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.addr_b(rf_addrw),
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.di_b(rf_dataw)
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);
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`else
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`ifdef OR1200_RFRAM_GENERIC
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//
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// Instantiation of generic (flip-flop based) register file
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//
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or1200_rfram_generic rf_a(
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// Clock and reset
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.clk(clk),
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.rst(rst),
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// Port A
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.ce_a(rf_ena),
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.addr_a(rf_addra),
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.do_a(from_rfa),
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// Port B
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.ce_b(rf_enb),
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.addr_b(addrb),
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.do_b(from_rfb),
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// Port W
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.ce_w(rf_we),
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.we_w(rf_we),
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.addr_w(rf_addrw),
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.di_w(rf_dataw)
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);
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`else
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//
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// RFRAM type not specified
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//
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initial begin
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$display("Define RFRAM type.");
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$finish;
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end
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`endif
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`endif
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`endif
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endmodule
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