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/* $Id: aeMB2_intu.v,v 1.7 2008-05-01 12:00:18 sybreon Exp $ ** ** AEMB2 EDK 6.2 COMPATIBLE CORE ** Copyright (C) 2004-2008 Shawn Tan <shawn.tan@aeste.net> ** ** This file is part of AEMB. ** ** AEMB 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 3 of the ** License, or (at your option) any later version. ** ** AEMB 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 AEMB. If not, see <http:**www.gnu.org/licenses/>. */ /** * One Cycle Integer Unit * @file aeMB2_intu.v * This implements a single cycle integer unit. It performs all basic arithmetic, shift, and logic operations. */ module aeMB2_intu (/*AUTOARG*/ // Outputs mem_ex, bpc_ex, alu_ex, alu_mx, msr_ex, sfr_mx, // Inputs opc_of, opa_of, opb_of, opd_of, imm_of, rd_of, ra_of, gclk, grst, dena, gpha ); parameter AEMB_DWB = 32; parameter AEMB_IWB = 32; parameter AEMB_HTX = 1; output [31:2] mem_ex; output [31:2] bpc_ex; output [31:0] alu_ex, alu_mx; //input [2:0] mux_of; input [5:0] opc_of; input [31:0] opa_of; input [31:0] opb_of; input [31:0] opd_of; input [15:0] imm_of; input [4:0] rd_of, ra_of; output [9:0] msr_ex; output [31:0] sfr_mx; // SYS signals input gclk, grst, dena, gpha; /*AUTOREG*/ // Beginning of automatic regs (for this module's undeclared outputs) reg [31:0] alu_ex; reg [31:0] alu_mx; reg [31:2] bpc_ex; reg [31:2] mem_ex; reg [31:0] sfr_mx; // End of automatics localparam [2:0] MUX_SFR = 3'o7, MUX_BSF = 3'o6, MUX_MUL = 3'o5, MUX_MEM = 3'o4, MUX_RPC = 3'o2, MUX_ALU = 3'o1, MUX_NOP = 3'o0; reg rMSR_C, rMSR_EE, rMSR_EIP, rMSR_CC, rMSR_MTX, rMSR_DTE, rMSR_ITE, rMSR_BIP, rMSR_IE, rMSR_BE; // Infer a ADD with carry cell because ADDSUB cannot be inferred // across technologies. reg [31:0] add_ex; reg add_c; wire [31:0] wADD; wire wADC; wire fCCC = !opc_of[5] & opc_of[1]; // & !opc_of[4] wire fSUB = !opc_of[5] & opc_of[0]; // & !opc_of[4] wire fCMP = !opc_of[3] & imm_of[1]; // unsigned only wire wCMP = (fCMP) ? !wADC : wADD[31]; // cmpu adjust wire [31:0] wOPA = (fSUB) ? ~opa_of : opa_of; wire wOPC = (fCCC) ? rMSR_CC : fSUB; assign {wADC, wADD} = (opb_of + wOPA) + wOPC; // add carry always @(/*AUTOSENSE*/wADC or wADD or wCMP) begin {add_c, add_ex} <= #1 {wADC, wCMP, wADD[30:0]}; // add with carry end // SHIFT/LOGIC/MOVE reg [31:0] slm_ex; always @(/*AUTOSENSE*/imm_of or opa_of or opb_of or opc_of or rMSR_CC) case (opc_of[2:0]) // LOGIC 3'o0: slm_ex <= #1 opa_of | opb_of; 3'o1: slm_ex <= #1 opa_of & opb_of; 3'o2: slm_ex <= #1 opa_of ^ opb_of; 3'o3: slm_ex <= #1 opa_of & ~opb_of; // SHIFT/SEXT 3'o4: case ({imm_of[6:5],imm_of[0]}) 3'o1: slm_ex <= #1 {opa_of[31],opa_of[31:1]}; // SRA 3'o3: slm_ex <= #1 {rMSR_CC,opa_of[31:1]}; // SRC 3'o5: slm_ex <= #1 {1'b0,opa_of[31:1]}; // SRL 3'o6: slm_ex <= #1 {{(24){opa_of[7]}}, opa_of[7:0]}; // SEXT8 3'o7: slm_ex <= #1 {{(16){opa_of[15]}}, opa_of[15:0]}; // SEXT16 default: slm_ex <= #1 32'hX; endcase // case ({imm_of[6:5],imm_of[0]}) // MFS/MTS/MSET/MCLR //3'o5: slm_ex <= #1 sfr_of; // BRL (PC from SFR) //3'o6: slm_ex <= #1 sfr_of; default: slm_ex <= #1 32'hX; endcase // case (opc_of[2:0]) // ALU RESULT always @(posedge gclk) if (grst) begin /*AUTORESET*/ // Beginning of autoreset for uninitialized flops alu_ex <= 32'h0; alu_mx <= 32'h0; bpc_ex <= 30'h0; mem_ex <= 30'h0; // End of automatics end else if (dena) begin alu_mx <= #1 alu_ex; alu_ex <= #1 (opc_of[5]) ? slm_ex : add_ex; mem_ex <= #1 wADD[AEMB_DWB-1:2]; // LXX/SXX bpc_ex <= #1 (!opc_of[0] & ra_of[3]) ? // check for BRA opb_of[AEMB_IWB-1:2] : // BRA only wADD[AEMB_IWB-1:2]; // RTD/BCC/BR end // MSR SECTION /* MSR REGISTER We should keep common configuration bits in the lower 16-bits of the MSR in order to avoid using the IMMI instruction. MSR bits 31 - CC (carry copy) 30 - HTE (hardware thread enabled) 29 - PHA (current phase) 7 - DTE (data cache enable) 5 - ITE (instruction cache enable) 4 - MTX (hardware mutex bit) 3 - BIP (break in progress) 2 - C (carry flag) 1 - IE (interrupt enable) 0 - BE (bus-lock enable) */ assign msr_ex = { rMSR_EIP, rMSR_EE, rMSR_DTE, 1'b0, rMSR_ITE, rMSR_MTX, rMSR_BIP, rMSR_C, rMSR_IE, rMSR_BE }; // MSRSET/MSRCLR (small ALU) wire [9:0] wRES = (ra_of[0]) ? (msr_ex[9:0]) & ~imm_of[9:0] : // MSRCLR (msr_ex[9:0]) | imm_of[9:0]; // MSRSET // 0 - Break // 1 - Interrupt // 2 - Exception // 3 - Reserved // break wire fRTBD = (opc_of == 6'o55) & rd_of[1]; wire fBRKB = ((opc_of == 6'o46) | (opc_of == 6'o56)) & (ra_of[4:0] == 5'hC); // interrupt wire fRTID = (opc_of == 6'o55) & rd_of[0]; wire fBRKI = (opc_of == 6'o56) & (ra_of[4:0] == 5'hD); // exception wire fRTED = (opc_of == 6'o55) & rd_of[2]; wire fBRKE = (opc_of == 6'o56) & (ra_of[4:0] == 5'hE); wire fMOV = (opc_of == 6'o45); wire fMTS = fMOV & &imm_of[15:14]; wire fMOP = fMOV & ~|imm_of[15:14]; reg [31:0] sfr_ex; always @(posedge gclk) if (grst) begin /*AUTORESET*/ // Beginning of autoreset for uninitialized flops rMSR_BE <= 1'h0; rMSR_BIP <= 1'h0; rMSR_DTE <= 1'h0; rMSR_EE <= 1'h0; rMSR_EIP <= 1'h0; rMSR_IE <= 1'h0; rMSR_ITE <= 1'h0; rMSR_MTX <= 1'h0; sfr_ex <= 32'h0; sfr_mx <= 32'h0; // End of automatics end else if (dena) begin // if (grst) sfr_mx <= #1 sfr_ex; sfr_ex <= #1 {rMSR_CC, AEMB_HTX[0], gpha, 21'd0, rMSR_DTE, 1'b0, rMSR_ITE, rMSR_MTX, rMSR_BIP, rMSR_CC, rMSR_IE, rMSR_BE }; rMSR_DTE <= #1 (fMTS) ? opa_of[7] : (fMOP) ? wRES[7] : rMSR_DTE; rMSR_ITE <= #1 (fMTS) ? opa_of[5] : (fMOP) ? wRES[5] : rMSR_ITE; rMSR_MTX <= #1 (fMTS) ? opa_of[4] : (fMOP) ? wRES[4] : rMSR_MTX; rMSR_BE <= #1 (fMTS) ? opa_of[0] : (fMOP) ? wRES[0] : rMSR_BE; rMSR_IE <= #1 (fBRKI) ? 1'b0 : (fRTID) ? 1'b1 : (fMTS) ? opa_of[1] : (fMOP) ? wRES[1] : rMSR_IE; rMSR_BIP <= #1 (fBRKB) ? 1'b1 : (fRTBD) ? 1'b0 : (fMTS) ? opa_of[3] : (fMOP) ? wRES[3] : rMSR_BIP; rMSR_EE <= #1 (fBRKE) ? 1'b0 : (fRTED) ? 1'b1 : (fMTS) ? opa_of[8] : (fMOP) ? wRES[8] : rMSR_EE; rMSR_EIP <= #1 (fBRKE) ? 1'b1 : (fRTED) ? 1'b0 : (fMTS) ? opa_of[9] : (fMOP) ? wRES[9] : rMSR_EIP; /* case ({fMTS, fMOP}) 2'o2: {rMSR_DTE, rMSR_ITE, rMSR_MTX, rMSR_BE} <= #1 {opa_of[7], opa_of[5], opa_of[4], opa_of[0]}; 2'o1: {rMSR_DTE, rMSR_ITE, rMSR_MTX, rMSR_BE} <= #1 {wRES[7], wRES[5], wRES[4], wRES[0]}; default: {rMSR_DTE, rMSR_ITE, rMSR_MTX, rMSR_BE} <= #1 {rMSR_DTE, rMSR_ITE, rMSR_MTX, rMSR_BE}; endcase // case ({fMTS, fMOP}) case ({fMTS, fMOP}) 2'o2: {rMSR_BIP, rMSR_IE} <= #1 {opa_of[3], opa_of[1]}; 2'o1: {rMSR_BIP, rMSR_IE} <= #1 {wRES[3], wRES[1]}; default: begin rMSR_BIP <= #1 (fBRKB | fRTBD) ? !rMSR_BIP : rMSR_BIP; rMSR_IE <= #1 (fBRKI | fRTID) ? !rMSR_IE : rMSR_IE; end endcase // case ({fMTS, fMOP}) */ end // if (dena) // BARREL C wire fADDSUB = !opc_of[5] & !opc_of[4] & !opc_of[2]; // (opc_of[5:2] == 4'h0) | (opc_of[5:2] == 4'h2); wire fSHIFT = (opc_of == 6'o44) & &imm_of[6:5]; always @(posedge gclk) if (grst) begin /*AUTORESET*/ end else if (dena) begin end always @(posedge gclk) if (grst) begin /*AUTORESET*/ // Beginning of autoreset for uninitialized flops rMSR_C <= 1'h0; rMSR_CC <= 1'h0; // End of automatics end else if (dena) begin rMSR_CC <= #1 rMSR_C; rMSR_C <= #1 (fMTS) ? opa_of[2] : (fMOP) ? wRES[2] : (fSHIFT) ? opa_of[0] : // SRA/SRL/SRC (fADDSUB) ? add_c : // ADD/SUB/ADDC/SUBC rMSR_CC; /* case ({fMTS,fMOP,fSHIFT,fADDSUB}) 4'h8: rMSR_C <= #1 opa_of[2]; 4'h4: rMSR_C <= #1 wRES[2]; 4'h2: rMSR_C <= #1 opa_of[0]; 4'h1: rMSR_C <= #1 add_c; default: rMSR_C <= #1 rMSR_CC; endcase // case ({fMTS,fMOP,fSHIFT,fADDSUB}) */ end endmodule // aeMB2_intu
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