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////////////////////////////////////////////////////////////////// // // // Decompiler for Amber 25 Core // // // // This file is part of the Amber project // // http://www.opencores.org/project,amber // // // // Description // // Decompiler for debugging core - not synthesizable // // Shows instruction in Execute Stage at last clock of // // the instruction // // // // Author(s): // // - Conor Santifort, csantifort.amber@gmail.com // // // ////////////////////////////////////////////////////////////////// // // // Copyright (C) 2011 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 // // // ////////////////////////////////////////////////////////////////// `include "global_timescale.vh" `include "global_defines.vh" `include "a25_config_defines.vh" module a25_decompile ( input i_clk, input i_core_stall, input [31:0] i_instruction, input i_instruction_valid, input i_instruction_undefined, input i_instruction_execute, input [2:0] i_interrupt, // non-zero value means interrupt triggered input i_interrupt_state, input [31:0] i_instruction_address, input [2:0] i_pc_sel, input i_pc_wen ); `include "a25_localparams.vh" `ifdef A25_DECOMPILE integer i; wire [31:0] imm32; wire [7:0] imm8; wire [11:0] offset12; wire [7:0] offset8; wire [3:0] reg_n, reg_d, reg_m, reg_s; wire [4:0] shift_imm; wire [3:0] opcode; wire [3:0] condition; wire [3:0] type; wire opcode_compare; wire opcode_move; wire no_shift; wire shift_op_imm; wire [1:0] mtrans_type; wire s_bit; reg [(5*8)-1:0] xINSTRUCTION_EXECUTE; reg [(5*8)-1:0] xINSTRUCTION_EXECUTE_R = "--- "; wire [(8*8)-1:0] TYPE_NAME; reg [3:0] fchars; reg [31:0] execute_address = 'd0; reg [2:0] interrupt_d1; reg [31:0] execute_instruction = 'd0; reg execute_now = 'd0; reg execute_valid = 'd0; reg execute_undefined = 'd0; // ======================================================== // Delay instruction to Execute stage // ======================================================== always @( posedge i_clk ) if ( !i_core_stall && i_instruction_valid ) begin execute_instruction <= i_instruction; execute_address <= i_instruction_address; execute_undefined <= i_instruction_undefined; execute_now <= 1'd1; end else execute_now <= 1'd0; always @ ( posedge i_clk ) if ( !i_core_stall ) execute_valid <= i_instruction_valid; // ======================================================== // Open File // ======================================================== integer decompile_file; initial #1 decompile_file = $fopen(`A25_DECOMPILE_FILE, "w"); // ======================================================== // Fields within the instruction // ======================================================== assign opcode = execute_instruction[24:21]; assign condition = execute_instruction[31:28]; assign s_bit = execute_instruction[20]; assign reg_n = execute_instruction[19:16]; assign reg_d = execute_instruction[15:12]; assign reg_m = execute_instruction[3:0]; assign reg_s = execute_instruction[11:8]; assign shift_imm = execute_instruction[11:7]; assign offset12 = execute_instruction[11:0]; assign offset8 = {execute_instruction[11:8], execute_instruction[3:0]}; assign imm8 = execute_instruction[7:0]; assign no_shift = execute_instruction[11:4] == 8'h0; assign mtrans_type = execute_instruction[24:23]; assign opcode_compare = opcode == CMP || opcode == CMN || opcode == TEQ || opcode == TST ; assign opcode_move = opcode == MOV || opcode == MVN ; assign shift_op_imm = type == REGOP && execute_instruction[25] == 1'd1; assign imm32 = execute_instruction[11:8] == 4'h0 ? { 24'h0, imm8[7:0] } : execute_instruction[11:8] == 4'h1 ? { imm8[1:0], 24'h0, imm8[7:2] } : execute_instruction[11:8] == 4'h2 ? { imm8[3:0], 24'h0, imm8[7:4] } : execute_instruction[11:8] == 4'h3 ? { imm8[5:0], 24'h0, imm8[7:6] } : execute_instruction[11:8] == 4'h4 ? { imm8[7:0], 24'h0 } : execute_instruction[11:8] == 4'h5 ? { 2'h0, imm8[7:0], 22'h0 } : execute_instruction[11:8] == 4'h6 ? { 4'h0, imm8[7:0], 20'h0 } : execute_instruction[11:8] == 4'h7 ? { 6'h0, imm8[7:0], 18'h0 } : execute_instruction[11:8] == 4'h8 ? { 8'h0, imm8[7:0], 16'h0 } : execute_instruction[11:8] == 4'h9 ? { 10'h0, imm8[7:0], 14'h0 } : execute_instruction[11:8] == 4'ha ? { 12'h0, imm8[7:0], 12'h0 } : execute_instruction[11:8] == 4'hb ? { 14'h0, imm8[7:0], 10'h0 } : execute_instruction[11:8] == 4'hc ? { 16'h0, imm8[7:0], 8'h0 } : execute_instruction[11:8] == 4'hd ? { 18'h0, imm8[7:0], 6'h0 } : execute_instruction[11:8] == 4'he ? { 20'h0, imm8[7:0], 4'h0 } : { 22'h0, imm8[7:0], 2'h0 } ; // ======================================================== // Instruction decode // ======================================================== // the order of these matters assign type = {execute_instruction[27:23], execute_instruction[21:20], execute_instruction[11:4] } == { 5'b00010, 2'b00, 8'b00001001 } ? SWAP : // Before REGOP {execute_instruction[27:22], execute_instruction[7:4] } == { 6'b000000, 4'b1001 } ? MULT : // Before REGOP {execute_instruction[27:26] } == { 2'b00 } ? REGOP : {execute_instruction[27:26] } == { 2'b01 } ? TRANS : {execute_instruction[27:25] } == { 3'b100 } ? MTRANS : {execute_instruction[27:25] } == { 3'b101 } ? BRANCH : {execute_instruction[27:25] } == { 3'b110 } ? CODTRANS : {execute_instruction[27:24], execute_instruction[4] } == { 4'b1110, 1'b0 } ? COREGOP : {execute_instruction[27:24], execute_instruction[4] } == { 4'b1110, 1'b1 } ? CORTRANS : SWI ; // // Convert some important signals to ASCII // so their values can easily be displayed on a waveform viewer // assign TYPE_NAME = type == REGOP ? "REGOP " : type == MULT ? "MULT " : type == SWAP ? "SWAP " : type == TRANS ? "TRANS " : type == MTRANS ? "MTRANS " : type == BRANCH ? "BRANCH " : type == CODTRANS ? "CODTRANS" : type == COREGOP ? "COREGOP " : type == CORTRANS ? "CORTRANS" : type == SWI ? "SWI " : "UNKNOWN " ; always @* begin if ( !execute_now ) begin xINSTRUCTION_EXECUTE = xINSTRUCTION_EXECUTE_R; end // stalled else if ( type == REGOP && opcode == ADC ) xINSTRUCTION_EXECUTE = "adc "; else if ( type == REGOP && opcode == ADD ) xINSTRUCTION_EXECUTE = "add "; else if ( type == REGOP && opcode == AND ) xINSTRUCTION_EXECUTE = "and "; else if ( type == BRANCH && execute_instruction[24] == 1'b0 ) xINSTRUCTION_EXECUTE = "b "; else if ( type == REGOP && opcode == BIC ) xINSTRUCTION_EXECUTE = "bic "; else if ( type == BRANCH && execute_instruction[24] == 1'b1 ) xINSTRUCTION_EXECUTE = "bl "; else if ( type == COREGOP ) xINSTRUCTION_EXECUTE = "cdp "; else if ( type == REGOP && opcode == CMN ) xINSTRUCTION_EXECUTE = "cmn "; else if ( type == REGOP && opcode == CMP ) xINSTRUCTION_EXECUTE = "cmp "; else if ( type == REGOP && opcode == EOR ) xINSTRUCTION_EXECUTE = "eor "; else if ( type == CODTRANS && execute_instruction[20] == 1'b1 ) xINSTRUCTION_EXECUTE = "ldc "; else if ( type == MTRANS && execute_instruction[20] == 1'b1 ) xINSTRUCTION_EXECUTE = "ldm "; else if ( type == TRANS && {execute_instruction[22],execute_instruction[20]} == {1'b0, 1'b1} ) xINSTRUCTION_EXECUTE = "ldr "; else if ( type == TRANS && {execute_instruction[22],execute_instruction[20]} == {1'b1, 1'b1} ) xINSTRUCTION_EXECUTE = "ldrb "; else if ( type == CORTRANS && execute_instruction[20] == 1'b0 ) xINSTRUCTION_EXECUTE = "mcr "; else if ( type == MULT && execute_instruction[21] == 1'b1 ) xINSTRUCTION_EXECUTE = "mla "; else if ( type == REGOP && opcode == MOV ) xINSTRUCTION_EXECUTE = "mov "; else if ( type == CORTRANS && execute_instruction[20] == 1'b1 ) xINSTRUCTION_EXECUTE = "mrc "; else if ( type == MULT && execute_instruction[21] == 1'b0 ) xINSTRUCTION_EXECUTE = "mul "; else if ( type == REGOP && opcode == MVN ) xINSTRUCTION_EXECUTE = "mvn "; else if ( type == REGOP && opcode == ORR ) xINSTRUCTION_EXECUTE = "orr "; else if ( type == REGOP && opcode == RSB ) xINSTRUCTION_EXECUTE = "rsb "; else if ( type == REGOP && opcode == RSC ) xINSTRUCTION_EXECUTE = "rsc "; else if ( type == REGOP && opcode == SBC ) xINSTRUCTION_EXECUTE = "sbc "; else if ( type == CODTRANS && execute_instruction[20] == 1'b0 ) xINSTRUCTION_EXECUTE = "stc "; else if ( type == MTRANS && execute_instruction[20] == 1'b0 ) xINSTRUCTION_EXECUTE = "stm "; else if ( type == TRANS && {execute_instruction[22],execute_instruction[20]} == {1'b0, 1'b0} ) xINSTRUCTION_EXECUTE = "str "; else if ( type == TRANS && {execute_instruction[22],execute_instruction[20]} == {1'b1, 1'b0} ) xINSTRUCTION_EXECUTE = "strb "; else if ( type == REGOP && opcode == SUB ) xINSTRUCTION_EXECUTE = "sub "; else if ( type == SWI ) xINSTRUCTION_EXECUTE = "swi "; else if ( type == SWAP && execute_instruction[22] == 1'b0 ) xINSTRUCTION_EXECUTE = "swp "; else if ( type == SWAP && execute_instruction[22] == 1'b1 ) xINSTRUCTION_EXECUTE = "swpb "; else if ( type == REGOP && opcode == TEQ ) xINSTRUCTION_EXECUTE = "teq "; else if ( type == REGOP && opcode == TST ) xINSTRUCTION_EXECUTE = "tst "; else xINSTRUCTION_EXECUTE = "unkow"; end always @ ( posedge i_clk ) xINSTRUCTION_EXECUTE_R <= xINSTRUCTION_EXECUTE; // ================================================================================= // Memory Reads and Writes // ================================================================================= reg [31:0] tmp_address; always @( posedge i_clk ) begin // Data Write if ( get_1bit_signal(0) && !get_1bit_signal(3) ) begin $fwrite(decompile_file, "%09d write addr ", `U_TB.clk_count); tmp_address = get_32bit_signal(2); fwrite_hex_drop_zeros(decompile_file, {tmp_address [31:2], 2'd0} ); $fwrite(decompile_file, ", data %08h, be %h", get_32bit_signal(3), // u_cache.i_write_data get_4bit_signal (0)); // u_cache.i_byte_enable $fwrite(decompile_file, "\n"); end // Data Read if ( get_1bit_signal(4) && !get_1bit_signal(1) ) begin $fwrite(decompile_file, "%09d read addr ", `U_TB.clk_count); tmp_address = get_32bit_signal(5); fwrite_hex_drop_zeros(decompile_file, {tmp_address[31:2], 2'd0} ); $fwrite(decompile_file, ", data %08h to ", get_32bit_signal(4)); warmreg(get_4bit_signal(1)); $fwrite(decompile_file, "\n"); end // instruction if ( execute_now ) begin // Interrupts override instructions that are just starting if ( interrupt_d1 == 3'd0 || interrupt_d1 == 3'd7 ) begin $fwrite(decompile_file,"%09d ", `U_TB.clk_count); // Right justify the address if ( execute_address < 32'h10) $fwrite(decompile_file," %01x: ", {execute_address[ 3:1], 1'd0}); else if ( execute_address < 32'h100) $fwrite(decompile_file," %02x: ", {execute_address[ 7:1], 1'd0}); else if ( execute_address < 32'h1000) $fwrite(decompile_file," %03x: ", {execute_address[11:1], 1'd0}); else if ( execute_address < 32'h10000) $fwrite(decompile_file," %04x: ", {execute_address[15:1], 1'd0}); else if ( execute_address < 32'h100000) $fwrite(decompile_file," %05x: ", {execute_address[19:1], 1'd0}); else if ( execute_address < 32'h1000000) $fwrite(decompile_file," %06x: ", {execute_address[23:1], 1'd0}); else if ( execute_address < 32'h10000000) $fwrite(decompile_file," %07x: ", {execute_address[27:1], 1'd0}); else $fwrite(decompile_file,"%8x: ", {execute_address[31:1], 1'd0}); // Mark that the instruction is not being executed // condition field in execute stage allows instruction to execute ? if (!i_instruction_execute) begin $fwrite(decompile_file,"-"); if ( type == SWI ) $display ("Cycle %09d SWI not taken *************", `U_TB.clk_count); end else $fwrite(decompile_file," "); // ======================================== // print the instruction name // ======================================== case (numchars( xINSTRUCTION_EXECUTE )) 4'd1: $fwrite(decompile_file,"%s", xINSTRUCTION_EXECUTE[39:32] ); 4'd2: $fwrite(decompile_file,"%s", xINSTRUCTION_EXECUTE[39:24] ); 4'd3: $fwrite(decompile_file,"%s", xINSTRUCTION_EXECUTE[39:16] ); 4'd4: $fwrite(decompile_file,"%s", xINSTRUCTION_EXECUTE[39: 8] ); default: $fwrite(decompile_file,"%s", xINSTRUCTION_EXECUTE[39: 0] ); endcase fchars = 8 - numchars(xINSTRUCTION_EXECUTE); // Print the Multiple transfer type if (type == MTRANS ) begin w_mtrans_type; fchars = fchars - 2; end // Print the s bit if ( ((type == REGOP && !opcode_compare) || type == MULT ) && s_bit == 1'b1 ) begin $fwrite(decompile_file,"s"); fchars = fchars - 1; end // Print the p bit if ( type == REGOP && opcode_compare && s_bit == 1'b1 && reg_d == 4'd15 ) begin $fwrite(decompile_file,"p"); fchars = fchars - 1; end // Print the condition code if ( condition != AL ) begin wcond; fchars = fchars - 2; end // Align spaces after instruction case ( fchars ) 4'd0: $fwrite(decompile_file,""); 4'd1: $fwrite(decompile_file," "); 4'd2: $fwrite(decompile_file," "); 4'd3: $fwrite(decompile_file," "); 4'd4: $fwrite(decompile_file," "); 4'd5: $fwrite(decompile_file," "); 4'd6: $fwrite(decompile_file," "); 4'd7: $fwrite(decompile_file," "); 4'd8: $fwrite(decompile_file," "); default: $fwrite(decompile_file," "); endcase // ======================================== // print the arguments for the instruction // ======================================== case ( type ) REGOP: regop_args; TRANS: trans_args; MTRANS: mtrans_args; BRANCH: branch_args; MULT: mult_args; SWAP: swap_args; CODTRANS: codtrans_args; COREGOP: begin // `TB_ERROR_MESSAGE $write("Coregop not implemented in decompiler yet\n"); end CORTRANS: cortrans_args; SWI: $fwrite(decompile_file,"#0x%06h", execute_instruction[23:0]); default: begin `TB_ERROR_MESSAGE $write("Unknown Instruction Type ERROR\n"); end endcase $fwrite( decompile_file,"\n" ); end // Undefined Instruction Interrupts if ( i_instruction_execute && execute_undefined ) begin $fwrite( decompile_file,"%09d interrupt undefined instruction", `U_TB.clk_count ); $fwrite( decompile_file,", return addr " ); $fwrite( decompile_file,"%08x\n", pcf(get_reg_val(5'd21)-4'd4) ); end // Software Interrupt if ( i_instruction_execute && type == SWI ) begin $fwrite( decompile_file,"%09d interrupt swi", `U_TB.clk_count ); $fwrite( decompile_file,", return addr " ); $fwrite( decompile_file,"%08x\n", pcf(get_reg_val(5'd21)-4'd4) ); end end end always @( posedge i_clk ) if ( !i_core_stall ) begin interrupt_d1 <= i_interrupt; // Asynchronous Interrupts if ( interrupt_d1 != 3'd0 && i_interrupt_state ) begin $fwrite( decompile_file,"%09d interrupt ", `U_TB.clk_count ); case ( interrupt_d1 ) 3'd1: $fwrite( decompile_file,"data abort" ); 3'd2: $fwrite( decompile_file,"firq" ); 3'd3: $fwrite( decompile_file,"irq" ); 3'd4: $fwrite( decompile_file,"address exception" ); 3'd5: $fwrite( decompile_file,"instruction abort" ); default: $fwrite( decompile_file,"unknown type" ); endcase $fwrite( decompile_file,", return addr " ); case ( interrupt_d1 ) 3'd1: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd16))); 3'd2: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd17))); 3'd3: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd18))); 3'd4: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd19))); 3'd5: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd19))); 3'd7: $fwrite(decompile_file,"%08h\n", pcf(get_reg_val(5'd20))); default: ; endcase end end // jump // Dont print a jump message for interrupts always @( posedge i_clk ) if ( i_pc_sel != 3'd0 && i_pc_wen && !i_core_stall && i_instruction_execute && i_interrupt == 3'd0 && !execute_undefined && type != SWI && execute_address != get_32bit_signal(0) // Don't print jump to same address ) begin $fwrite(decompile_file,"%09d jump from ", `U_TB.clk_count); fwrite_hex_drop_zeros(decompile_file, pcf(execute_address)); $fwrite(decompile_file," to "); fwrite_hex_drop_zeros(decompile_file, pcf(get_32bit_signal(0)) ); // u_execute.pc_nxt $fwrite(decompile_file,", r0 %08h, ", get_reg_val ( 5'd0 )); $fwrite(decompile_file,"r1 %08h\n", get_reg_val ( 5'd1 )); end // ================================================================================= // Tasks // ================================================================================= // Write Condition field task wcond; begin case( condition) 4'h0: $fwrite(decompile_file,"eq"); 4'h1: $fwrite(decompile_file,"ne"); 4'h2: $fwrite(decompile_file,"cs"); 4'h3: $fwrite(decompile_file,"cc"); 4'h4: $fwrite(decompile_file,"mi"); 4'h5: $fwrite(decompile_file,"pl"); 4'h6: $fwrite(decompile_file,"vs"); 4'h7: $fwrite(decompile_file,"vc"); 4'h8: $fwrite(decompile_file,"hi"); 4'h9: $fwrite(decompile_file,"ls"); 4'ha: $fwrite(decompile_file,"ge"); 4'hb: $fwrite(decompile_file,"lt"); 4'hc: $fwrite(decompile_file,"gt"); 4'hd: $fwrite(decompile_file,"le"); 4'he: $fwrite(decompile_file," "); // Always default: $fwrite(decompile_file,"nv"); // Never endcase end endtask // ldm and stm types task w_mtrans_type; begin case( mtrans_type ) 4'h0: $fwrite(decompile_file,"da"); 4'h1: $fwrite(decompile_file,"ia"); 4'h2: $fwrite(decompile_file,"db"); 4'h3: $fwrite(decompile_file,"ib"); default: $fwrite(decompile_file,"xx"); endcase end endtask // e.g. mrc 15, 0, r9, cr0, cr0, {0} task cortrans_args; begin // Co-Processor Number $fwrite(decompile_file,"%1d, ", execute_instruction[11:8]); // opcode1 $fwrite(decompile_file,"%1d, ", execute_instruction[23:21]); // Rd [15:12] warmreg(reg_d); // CRn [19:16] $fwrite(decompile_file,", cr%1d", execute_instruction[19:16]); // CRm [3:0] $fwrite(decompile_file,", cr%1d", execute_instruction[3:0]); // Opcode2 [7:5] $fwrite(decompile_file,", {%1d}", execute_instruction[7:5]); end endtask // ldc 15, 0, r9, cr0, cr0, {0} task codtrans_args; begin // Co-Processor Number $fwrite(decompile_file,"%1d, ", execute_instruction[11:8]); // CRd [15:12] $fwrite(decompile_file,"cr%1d, ", execute_instruction[15:12]); // Rd [19:16] warmreg(reg_n); end endtask task branch_args; reg [31:0] shift_amount; begin if (execute_instruction[23]) // negative shift_amount = {~execute_instruction[23:0] + 24'd1, 2'd0}; else shift_amount = {execute_instruction[23:0], 2'd0}; if (execute_instruction[23]) // negative fwrite_hex_drop_zeros ( decompile_file, get_reg_val( 5'd21 ) - shift_amount ); else fwrite_hex_drop_zeros ( decompile_file, get_reg_val( 5'd21 ) + shift_amount ); end endtask task mult_args; begin warmreg(reg_n); // Rd is in the Rn position for MULT instructions $fwrite(decompile_file,", "); warmreg(reg_m); $fwrite(decompile_file,", "); warmreg(reg_s); if (execute_instruction[21]) // MLA begin $fwrite(decompile_file,", "); warmreg(reg_d); end end endtask task swap_args; begin warmreg(reg_d); $fwrite(decompile_file,", "); warmreg(reg_m); $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end endtask task regop_args; begin if (!opcode_compare) warmreg(reg_d); if (!opcode_move ) begin if (!opcode_compare) begin $fwrite(decompile_file,", "); if (reg_d < 4'd10 || reg_d > 4'd12) $fwrite(decompile_file," "); end warmreg(reg_n); $fwrite(decompile_file,", "); if (reg_n < 4'd10 || reg_n > 4'd12) $fwrite(decompile_file," "); end else begin $fwrite(decompile_file,", "); if (reg_d < 4'd10 || reg_d > 4'd12) $fwrite(decompile_file," "); end if (shift_op_imm) begin if (|imm32[31:15]) $fwrite(decompile_file,"#0x%08h", imm32); else $fwrite(decompile_file,"#%1d", imm32); end else // Rm begin warmreg(reg_m); if (execute_instruction[4]) // Register Shifts wshiftreg; else // Immediate shifts wshift; end end endtask task trans_args; begin warmreg(reg_d); // Destination register casez ({execute_instruction[25:23], execute_instruction[21], no_shift, offset12==12'd0}) 6'b0100?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", #-%1d]" , offset12); end 6'b0110?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", #%1d]" , offset12); end 6'b0100?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b0110?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b0101?? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", #-%1d]!", offset12); end 6'b0111?? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", #%1d]!" , offset12); end 6'b0000?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], #-%1d", offset12); end 6'b0010?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], #%1d" , offset12); end 6'b0001?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], #-%1d", offset12); end 6'b0011?0 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], #%1d" , offset12); end 6'b0000?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b0010?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b0001?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b0011?1 : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"]"); end 6'b11001? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", -"); warmreg(reg_m); $fwrite(decompile_file,"]"); end 6'b11101? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", "); warmreg(reg_m); $fwrite(decompile_file,"]"); end 6'b11011? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", -"); warmreg(reg_m); $fwrite(decompile_file,"]!"); end 6'b11111? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", "); warmreg(reg_m); $fwrite(decompile_file,"]!"); end 6'b10001? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], -"); warmreg(reg_m); end 6'b10101? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], "); warmreg(reg_m); end 6'b10011? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], -"); warmreg(reg_m); end 6'b10111? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], "); warmreg(reg_m); end 6'b11000? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", -"); warmreg(reg_m); wshift; $fwrite(decompile_file,"]"); end 6'b11100? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", "); warmreg(reg_m); wshift; $fwrite(decompile_file,"]"); end 6'b11010? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", -"); warmreg(reg_m); wshift; $fwrite(decompile_file,"]!");end 6'b11110? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,", "); warmreg(reg_m); wshift; $fwrite(decompile_file,"]!");end 6'b10000? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], -"); warmreg(reg_m); wshift; end 6'b10100? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], "); warmreg(reg_m); wshift; end 6'b10010? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], -"); warmreg(reg_m); wshift; end 6'b10110? : begin $fwrite(decompile_file,", ["); warmreg(reg_n); $fwrite(decompile_file,"], "); warmreg(reg_m); wshift; end endcase end endtask task mtrans_args; begin warmreg(reg_n); if (execute_instruction[21]) $fwrite(decompile_file,"!"); $fwrite(decompile_file,", {"); for (i=0;i<16;i=i+1) if (execute_instruction[i]) begin warmreg(i); if (more_to_come(execute_instruction[15:0], i)) $fwrite(decompile_file,", "); end $fwrite(decompile_file,"}"); // SDM: store the user mode registers, when in priviledged mode if (execute_instruction[22:20] == 3'b100) $fwrite(decompile_file,"^"); end endtask task wshift; begin // Check that its a valid shift operation. LSL by #0 is the null operator if (execute_instruction[6:5] != LSL || shift_imm != 5'd0) begin case(execute_instruction[6:5]) 2'd0: $fwrite(decompile_file,", lsl"); 2'd1: $fwrite(decompile_file,", lsr"); 2'd2: $fwrite(decompile_file,", asr"); 2'd3: if (shift_imm == 5'd0) $fwrite(decompile_file,", rrx"); else $fwrite(decompile_file,", ror"); endcase if (execute_instruction[6:5] != 2'd3 || shift_imm != 5'd0) $fwrite(decompile_file," #%1d", shift_imm); end end endtask task wshiftreg; begin case(execute_instruction[6:5]) 2'd0: $fwrite(decompile_file,", lsl "); 2'd1: $fwrite(decompile_file,", lsr "); 2'd2: $fwrite(decompile_file,", asr "); 2'd3: $fwrite(decompile_file,", ror "); endcase warmreg(reg_s); end endtask task warmreg; input [3:0] regnum; begin if (regnum < 4'd12) $fwrite(decompile_file,"r%1d", regnum); else case (regnum) 4'd12 : $fwrite(decompile_file,"ip"); 4'd13 : $fwrite(decompile_file,"sp"); 4'd14 : $fwrite(decompile_file,"lr"); 4'd15 : $fwrite(decompile_file,"pc"); endcase end endtask task fwrite_hex_drop_zeros; input [31:0] file; input [31:0] num; begin if (num[31:28] != 4'd0) $fwrite(file, "%x", num); else if (num[27:24] != 4'd0) $fwrite(file, "%x", num[27:0]); else if (num[23:20] != 4'd0) $fwrite(file, "%x", num[23:0]); else if (num[19:16] != 4'd0) $fwrite(file, "%x", num[19:0]); else if (num[15:12] != 4'd0) $fwrite(file, "%x", num[15:0]); else if (num[11:8] != 4'd0) $fwrite(file, "%x", num[11:0]); else if (num[7:4] != 4'd0) $fwrite(file, "%x", num[7:0]); else $fwrite(file, "%x", num[3:0]); end endtask // ================================================================================= // Functions // ================================================================================= // Get current value of register function [31:0] get_reg_val; input [4:0] regnum; begin case (regnum) 5'd0 : get_reg_val = `U_REGISTER_BANK.r0_out; 5'd1 : get_reg_val = `U_REGISTER_BANK.r1_out; 5'd2 : get_reg_val = `U_REGISTER_BANK.r2_out; 5'd3 : get_reg_val = `U_REGISTER_BANK.r3_out; 5'd4 : get_reg_val = `U_REGISTER_BANK.r4_out; 5'd5 : get_reg_val = `U_REGISTER_BANK.r5_out; 5'd6 : get_reg_val = `U_REGISTER_BANK.r6_out; 5'd7 : get_reg_val = `U_REGISTER_BANK.r7_out; 5'd8 : get_reg_val = `U_REGISTER_BANK.r8_out; 5'd9 : get_reg_val = `U_REGISTER_BANK.r9_out; 5'd10 : get_reg_val = `U_REGISTER_BANK.r10_out; 5'd11 : get_reg_val = `U_REGISTER_BANK.r11_out; 5'd12 : get_reg_val = `U_REGISTER_BANK.r12_out; 5'd13 : get_reg_val = `U_REGISTER_BANK.r13_out; 5'd14 : get_reg_val = `U_REGISTER_BANK.r14_out; 5'd15 : get_reg_val = `U_REGISTER_BANK.r15_out_rm; // the version of pc with status bits 5'd16 : get_reg_val = `U_REGISTER_BANK.r14_svc; 5'd17 : get_reg_val = `U_REGISTER_BANK.r14_firq; 5'd18 : get_reg_val = `U_REGISTER_BANK.r14_irq; 5'd19 : get_reg_val = `U_REGISTER_BANK.r14_svc; 5'd20 : get_reg_val = `U_REGISTER_BANK.r14_svc; 5'd21 : get_reg_val = `U_REGISTER_BANK.r15_out_rn; // the version of pc without status bits endcase end endfunction function [31:0] get_32bit_signal; input [2:0] num; begin case (num) 3'd0: get_32bit_signal = `U_EXECUTE.pc_nxt; 3'd1: get_32bit_signal = `U_EXECUTE.o_iaddress; 3'd2: get_32bit_signal = `U_EXECUTE.o_daddress; 3'd3: get_32bit_signal = `U_EXECUTE.o_write_data; // 3'd4: get_32bit_signal = `U_EXECUTE.read_data_filtered; 3'd4: get_32bit_signal = `U_EXECUTE.i_wb_read_data; 3'd5: get_32bit_signal = `U_WB.daddress_r; endcase end endfunction function get_1bit_signal; input [2:0] num; begin case (num) 3'd0: get_1bit_signal = `U_EXECUTE.o_write_enable; 3'd1: get_1bit_signal = `U_AMBER.mem_stall; 3'd2: get_1bit_signal = `U_EXECUTE.o_daddress_valid; 3'd3: get_1bit_signal = `U_AMBER.core_stall; 3'd4: get_1bit_signal = `U_WB.mem_read_data_valid_r; endcase end endfunction function [3:0] get_4bit_signal; input [2:0] num; begin case (num) 3'd0: get_4bit_signal = `U_EXECUTE.o_byte_enable; 3'd1: get_4bit_signal = `U_WB.mem_load_rd_r; endcase end endfunction function [3:0] numchars; input [(5*8)-1:0] xINSTRUCTION_EXECUTE; begin if (xINSTRUCTION_EXECUTE[31:0] == " ") numchars = 4'd1; else if (xINSTRUCTION_EXECUTE[23:0] == " ") numchars = 4'd2; else if (xINSTRUCTION_EXECUTE[15:0] == " ") numchars = 4'd3; else if (xINSTRUCTION_EXECUTE[7:0] == " ") numchars = 4'd4; else numchars = 4'd5; end endfunction function more_to_come; input [15:0] regs; input [31:0] i; begin case (i) 15 : more_to_come = 1'd0; 14 : more_to_come = regs[15] ? 1'd1 : 1'd0; 13 : more_to_come = |regs[15:14] ? 1'd1 : 1'd0; 12 : more_to_come = |regs[15:13] ? 1'd1 : 1'd0; 11 : more_to_come = |regs[15:12] ? 1'd1 : 1'd0; 10 : more_to_come = |regs[15:11] ? 1'd1 : 1'd0; 9 : more_to_come = |regs[15:10] ? 1'd1 : 1'd0; 8 : more_to_come = |regs[15: 9] ? 1'd1 : 1'd0; 7 : more_to_come = |regs[15: 8] ? 1'd1 : 1'd0; 6 : more_to_come = |regs[15: 7] ? 1'd1 : 1'd0; 5 : more_to_come = |regs[15: 6] ? 1'd1 : 1'd0; 4 : more_to_come = |regs[15: 5] ? 1'd1 : 1'd0; 3 : more_to_come = |regs[15: 4] ? 1'd1 : 1'd0; 2 : more_to_come = |regs[15: 3] ? 1'd1 : 1'd0; 1 : more_to_come = |regs[15: 2] ? 1'd1 : 1'd0; 0 : more_to_come = |regs[15: 1] ? 1'd1 : 1'd0; endcase end endfunction `endif endmodule
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