/* decoder.v - Implementation of instruction opcode decoding logic This file is part of the 9086 project. Copyright (c) 2023 Efthymios Kritikos This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ `include "exec_state_def.v" `include "alu_header.v" `include "ucode_header.v" `include "error_header.v" module microcode( input [`UCODE_ADDR_BITS-1:0] ADDR, output [`UCODE_DATA_BITS-1:0] DATA ); initial begin string ucode_path; if($value$plusargs("MICROCODE=%s",ucode_path))begin $readmemb(ucode_path,ucode_rom,0,`UCODE_SIZE-1); end else begin $display("Please supply microcode rom file as a runtime vvp argument +MICROCODE="); $finish; end end reg [`UCODE_DATA_BITS-1:0] ucode_rom [ 0:`UCODE_SIZE-1 ]; assign DATA=ucode_rom[ADDR]; endmodule module decoder( /* INPUTS */ input wire [15:0] CIR,input wire [15:0] FLAGS /* MICROCODE */ ,output reg [`UCODE_ADDR_BITS-1:0] seq_addr_entry, input wire SIMPLE_MICRO, input wire [`UCODE_ADDR_BITS-1:0] seq_addr_input /* OUTPUT */ ,output wire [`EXEC_STATE_BITS+`ERROR_BITS+65:0] OUTPUT, output reg DEPENDS_ON_PREVIOUS ); /* DEPENDS_ON_PREVIOUS - This encodes weather the instruction requires the previous to be finished in order to be decoded. This, for example, affects * conditional jumps since flags are checked during decode. */ reg [2:0]IN_MOD; assign OUTPUT[2:0] = IN_MOD; reg [2:0]RM; assign OUTPUT[5:3] = RM; reg memio_address_select; assign OUTPUT[6:6] = memio_address_select; reg MEM_OR_IO; assign OUTPUT[7:7] = MEM_OR_IO; reg [15:0] PARAM1; assign OUTPUT[23:8] = PARAM1; reg [15:0] PARAM2; assign OUTPUT[39:24] = PARAM2; reg [2:0]ALU_OP; assign OUTPUT[42:40] = ALU_OP; reg [1:0]in_alu_sel1; assign OUTPUT[44:43] = in_alu_sel1; reg [1:0]in_alu_sel2; assign OUTPUT[46:45] = in_alu_sel2; reg [2:0]OUT_MOD; assign OUTPUT[49:47] = OUT_MOD; reg [3:0]reg_read_port1_addr; assign OUTPUT[53:50] = reg_read_port1_addr; reg [3:0]reg_read_port2_addr; assign OUTPUT[57:54] = reg_read_port2_addr; reg [3:0]reg_write_addr; assign OUTPUT[61:58] = reg_write_addr; reg Wbit,Sbit,opcode_size; assign OUTPUT[64:62] = {Wbit,Sbit,opcode_size}; reg [`ERROR_BITS-1:0] ERROR; reg HALT; assign OUTPUT[`ERROR_BITS+65:65]={ERROR,HALT}; reg [`EXEC_STATE_BITS-1:0] next_state; assign OUTPUT[`EXEC_STATE_BITS+`ERROR_BITS+65:`ERROR_BITS+66] = next_state; /* verilator lint_off UNUSEDSIGNAL */ wire [`UCODE_DATA_BITS-1:0] ucode_data; /* verilator lint_on UNUSEDSIGNAL */ microcode ucode(seq_addr_input,ucode_data); `define invalid_instruction next_state=`EXEC_WAIT;ERROR<=`ERR_UNIMPL_INSTRUCTION;IN_MOD=3'b011;seq_addr_entry<=`UCODE_NO_INSTRUCTION; `define unimpl_addressing_mode next_state=`EXEC_WAIT;ERROR <= `ERR_UNIMPL_ADDRESSING_MODE;IN_MOD=3'b011;seq_addr_entry<=`UCODE_NO_INSTRUCTION; //TODO: A possible optimisation for instruction with 8bit parameter and //opcode_size=0 would be to set PARAM1 here instead of sending execution over //to EXEC_DE_LOAD_8_PARAM `define normal_instruction seq_addr_entry<=`UCODE_NO_INSTRUCTION;ERROR<=`ERR_NO_ERROR;HALT<=0;MEM_OR_IO=0; `define normal_microcoded ERROR<=`ERR_NO_ERROR;HALT<=0;MEM_OR_IO=0; // I use blocking for basically putting names on the different fields of CIR and // then branching off of that instead of the raw bits. otherwise the code // would be identical // verilator lint_off BLKSEQ always @( FLAGS or CIR or SIMPLE_MICRO or seq_addr_input ) begin if (SIMPLE_MICRO==0)begin casez({CIR[15:8],CIR[5:3]}) 11'b0000_010?_??? : begin /* ADD - Add Immediate word/byte to accumulator */ /* 0 0 0 0 0 1 0 W | DATA | DATA if W |*/ opcode_size=0; Wbit=CIR[8:8]; IN_MOD=3'b011; in_alu_sel1=2'b00; in_alu_sel2=2'b01; OUT_MOD=3'b011; MEM_OR_IO=0; reg_read_port2_addr={Wbit,3'b000}; reg_write_addr={Wbit,3'b000}; ALU_OP=`ALU_OP_ADD; memio_address_select=0; if(Wbit) next_state=`EXEC_DE_LOAD_16_PARAM; else next_state=`EXEC_DE_LOAD_8_PARAM; DEPENDS_ON_PREVIOUS<=0; `normal_instruction; end 11'b1000_00??_101, /* SUB */ 11'b1000_00??_000 : /* ADD */ begin /* ADD - Add Immediate word/byte to register/memory */ /* 1 0 0 0 0 0 S W | MOD 0 0 0 R/M | < DISP LO > | < DISP HI > | DATA | DATA if W | */ /* SUB - Subtract immediate word/byte from register/memory */ /* 1 0 0 0 0 0 S W | MOD 1 0 1 R/M | < DISP LO > | < DISP HI > | DATA | DATA if W | */ opcode_size=1; Wbit=CIR[8:8]; Sbit=CIR[9:9]; IN_MOD={1'b0,CIR[7:6]}; RM=CIR[2:0]; in_alu_sel1=2'b00; if(IN_MOD==3'b011)begin in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; reg_write_addr={Wbit,RM}; end else begin in_alu_sel2=2'b00; end OUT_MOD=IN_MOD; MEM_OR_IO=0; memio_address_select=0; case({Sbit,Wbit}) 2'b00,2'b11:begin next_state=`EXEC_DE_LOAD_8_PARAM; end 2'b01:begin next_state=`EXEC_DE_LOAD_16_PARAM; end default:begin `invalid_instruction end endcase case(CIR[5:3]) 3'b000: ALU_OP=`ALU_OP_ADD; 3'b101: ALU_OP=`ALU_OP_SUB_REVERSE; default:begin /*Should be impossible*/ `invalid_instruction end endcase DEPENDS_ON_PREVIOUS<=0; `normal_instruction; end 11'b1000_00??_111 : begin /* CMP - compare Immediate with register / memory */ /* 1 0 0 0 0 0 S W | MOD 1 1 1 R/M | < DISP LO > | < DISP HI > | DATA | DATA if W | */ opcode_size=1; Wbit=CIR[8:8]; Sbit=CIR[9:9]; IN_MOD={1'b0,CIR[7:6]}; RM=CIR[2:0]; if ( {Sbit,Wbit} == 2'b10 )begin `invalid_instruction end in_alu_sel1=2'b00; OUT_MOD=3'b100; MEM_OR_IO=0; ALU_OP=`ALU_OP_SUB_REVERSE; memio_address_select=0; if(IN_MOD==3'b011)begin /*compare register with param*/ in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; next_state=`EXEC_DE_LOAD_8_PARAM; end else begin /*compare register indirect access * with param */ in_alu_sel2=2'b00; next_state=`EXEC_DE_LOAD_16_PARAM; /*will then call MEMIO_READ*/ end DEPENDS_ON_PREVIOUS<=0; `normal_instruction; end 11'b1011_0???_??? : begin /* MOV - Move Immediate byte to register */ /* 1 0 1 1 W REG | DATA | DATA if W |*/ Wbit=CIR[11:11]; /* IS 0 */ opcode_size=0; IN_MOD=3'b011; in_alu_sel1=2'b00; in_alu_sel2=2'b00; OUT_MOD=3'b011; MEM_OR_IO=0; reg_write_addr={1'b0,CIR[10:8]}; PARAM1[7:0]=CIR[7:0]; PARAM2=0; ALU_OP=`ALU_OP_ADD; next_state=`EXEC_WRITE_ENTRY; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1011_1???_??? : begin /*MOV - Move Immediate word to register*/ Wbit=CIR[11:11]; /*IS 1 */ opcode_size=0; IN_MOD=3'b011; in_alu_sel1=2'b00; in_alu_sel2=2'b00; OUT_MOD=3'b011; MEM_OR_IO=0; reg_write_addr={1'b1,CIR[10:8]}; ALU_OP=`ALU_OP_ADD; PARAM2=0; next_state=`EXEC_DE_LOAD_16_PARAM; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1000_10??_??? : begin /* MOV - Reg/Mem to/from register */ /* 1 0 0 0 1 0 D W | MOD REG RM | < DISP LO > | < DISP HI > |*/ opcode_size=1; RM=CIR[2:0]; Wbit=CIR[8:8]; in_alu_sel1=2'b00; PARAM1=0; MEM_OR_IO=0; if(CIR[9:9] == 1)begin /* Mem/Reg to reg */ IN_MOD={1'b0,CIR[7:6]}; if(IN_MOD==3'b011)begin /*Reg to Reg*/ in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; next_state=`EXEC_WRITE_ENTRY; end else begin /*Mem to Reg*/ in_alu_sel2=2'b00; next_state=`EXEC_MEMIO_READ; end OUT_MOD=3'b011; reg_write_addr={Wbit,CIR[5:3]}; end else begin /* Reg to Mem/Reg */ IN_MOD=3'b011; OUT_MOD={1'b0,CIR[7:6]}; if(IN_MOD==3'b011)begin /*Reg to Reg*/ in_alu_sel2=2'b01; reg_write_addr={Wbit,RM}; next_state=`EXEC_WRITE_ENTRY; end else begin /*Reg to Mem*/ in_alu_sel2=2'b00; next_state=`EXEC_DE_LOAD_REG_TO_PARAM; end reg_read_port2_addr={Wbit,CIR[5:3]}; end ALU_OP=`ALU_OP_ADD; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b0100_????_???:begin//DEC /* DEC - Decrement Register */ /* | 0 1 0 0 1 REG | */ /* INC - Increment Register */ /* | 0 1 0 0 0 REG | */ opcode_size=0; Wbit=1; in_alu_sel1=2'b01; in_alu_sel2=2'b00; OUT_MOD=3'b011; MEM_OR_IO=0; IN_MOD=3'b011; PARAM2=1; reg_read_port1_addr={1'b1,CIR[10:8]}; reg_write_addr={1'b1,CIR[10:8]}; if(CIR[11:11]==0) ALU_OP=`ALU_OP_ADD; else ALU_OP=`ALU_OP_SUB; next_state=`EXEC_WRITE_ENTRY; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1111_111?_00? : begin /* INC - Register/Memory */ /* 1 1 1 1 1 1 1 W | MOD 0 0 0 R/M | < DISP LO> | < DISP HI> */ /* DEC - Register/Memory */ /* 1 1 1 1 1 1 1 W | MOD 0 0 1 R/M | < DISP LO> | < DISP HI> */ opcode_size=1; Wbit=CIR[8:8]; IN_MOD={1'b0,CIR[7:6]}; RM=CIR[2:0]; in_alu_sel2=(IN_MOD==3'b011)? 2'b01 : 2'b00; in_alu_sel1=2'b00;/* number 1 */ PARAM1=1; OUT_MOD=IN_MOD; MEM_OR_IO=0; /*in case IN_MOD=011 */ reg_read_port2_addr={1'b0,RM}; reg_write_addr={1'b0,RM}; ALU_OP=(CIR[3:3]==1)?`ALU_OP_SUB_REVERSE:`ALU_OP_ADD; if ( IN_MOD == 3'b011 ) next_state=`EXEC_WRITE_ENTRY; else next_state=`EXEC_MEMIO_READ; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1111_0100_??? : begin /* HLT - Halt */ /* 1 1 1 1 0 1 0 0 | */ opcode_size=0; IN_MOD=3'b011; HALT<=1; ERROR<=`ERR_NO_ERROR; MEM_OR_IO=0; seq_addr_entry<=`UCODE_NO_INSTRUCTION; next_state=`EXEC_WAIT; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b0011_110?_??? : begin /* CMP - Compare Immediate with accumulator */ /* 0 0 1 1 1 1 0 W | DATA | DATA if W |*/ /* */ /* NOTE: 8086 doc doesn't show the third byte but the */ /* W flag and my assembler seem to disagree */ Wbit=CIR[8:8]; opcode_size=0; IN_MOD=3'b011; in_alu_sel1=2'b00; in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,3'b000}; OUT_MOD=3'b100; ALU_OP=`ALU_OP_SUB_REVERSE; MEM_OR_IO=0; if(Wbit==1) next_state=`EXEC_DE_LOAD_16_PARAM; else begin PARAM1[7:0]=CIR[7:0]; next_state=`EXEC_WRITE_ENTRY; end `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b0111_????_???:begin /* Conditional relative jumps */ /* JE/JZ - Jump on Zero */ /* 0 1 1 1 0 1 0 0 | IP-INC8 |*/ /* JS - Jump on Sign */ /* 0 1 1 1 1 0 0 0 | IP-INC8 |*/ /* JNS -Jump on not Sign */ /* 0 1 1 1 1 0 0 1 | IP-INC8 |*/ /* .... */ Wbit=1; opcode_size=0; in_alu_sel1=2'b10; in_alu_sel2=2'b00; PARAM2={{8{CIR[7:7]}},CIR[7:0]}; ALU_OP=`ALU_OP_ADD_SIGNED_B; MEM_OR_IO=0; OUT_MOD=3'b101; case(CIR[11:9]) 3'b000: begin /* Jump on (not) Overflow */ if(FLAGS[11:11]==CIR[8:8]) next_state=`EXEC_NEXT_INSTRUCTION; else begin next_state=`EXEC_WRITE_ENTRY; end end 3'b010: begin /* Jump on (not) Zero */ if(FLAGS[6:6]==CIR[8:8]) next_state=`EXEC_NEXT_INSTRUCTION; else next_state=`EXEC_WRITE_ENTRY; end 3'b100: begin /* Jump on (not) Sign */ if(FLAGS[7:7]==CIR[8:8]) next_state=`EXEC_NEXT_INSTRUCTION; else next_state=`EXEC_WRITE_ENTRY; end 3'b101: begin /* Jump on (not) Parity */ if(FLAGS[2:2]==CIR[8:8]) next_state=`EXEC_NEXT_INSTRUCTION; else next_state=`EXEC_WRITE_ENTRY; end 3'b001: begin /* Jump on (not) Carry */ if(FLAGS[0:0]==CIR[8:8]) next_state=`EXEC_NEXT_INSTRUCTION; else next_state=`EXEC_WRITE_ENTRY; end default:begin `invalid_instruction; /*We don't support that condition*/ end endcase `normal_instruction; DEPENDS_ON_PREVIOUS<=1; memio_address_select=0; end 11'b1110_1011_???:begin /* JMP - Unconditional jump direct within segment (short) */ /* | 1 1 1 0 1 0 1 1 | IP-INC-LO | */ opcode_size=0; Wbit=1; in_alu_sel1=2'b10; in_alu_sel2=2'b00; PARAM2={{8{CIR[7:7]}},CIR[7:0]}; ALU_OP=`ALU_OP_ADD_SIGNED_B; OUT_MOD=3'b101; MEM_OR_IO=0; next_state=`EXEC_WRITE_ENTRY; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1110_1000_???:begin /* CALL - Direct call within segment */ /* 1 1 1 0 1 0 0 0 | IP-INC-LO | IP-INC-HI |*/ // Microcode instruction opcode_size=0; Wbit=1; Sbit=1; PARAM2=2; //subtract from sp seq_addr_entry<=`UCODE_CALL_ENTRY; `normal_microcoded DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1100_0011_???:begin /* RET - Return from call within segment */ /* | 1 1 0 0 0 0 1 1 | */ // Microcode instruction opcode_size=0; Wbit=1; Sbit=0; PARAM1=2; seq_addr_entry<=`UCODE_RET_ENTRY; `normal_microcoded DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1010_101?_???:begin /* STOS - Write byte/word to [DI] and increment accordingly */ /* | 1 0 1 0 1 0 1 W | */ opcode_size=0; Wbit=CIR[8:8]; Sbit=0; RM=3'b101; seq_addr_entry<=`UCODE_STOS_ENTRY; `normal_microcoded PARAM2=(Wbit==1)?2:1; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b0101_0???_???:begin /* PUSH - SP-=2; [SP]=REG */ /* | 0 1 0 1 0 REG | */ opcode_size=0; Wbit=1; Sbit=0; PARAM2=2; reg_read_port2_addr={1'b1,CIR[10:8]}; seq_addr_entry<=`UCODE_PUSH_ENTRY; `normal_microcoded memio_address_select=0; DEPENDS_ON_PREVIOUS<=0; end 11'b1111_011?_000:begin /* TEST - Bitwise AND of immediate and registers/memmory affecting only flags */ /* 1 1 1 1 0 1 1 W | MOD 0 0 0 R/M | < DISP-LO > | < DISP-HI > | DATA | DATA if W */ opcode_size=1; Wbit=CIR[8:8]; IN_MOD={1'b0,CIR[7:6]}; RM={CIR[2:0]}; MEM_OR_IO=0; if(Wbit==1)begin next_state=`EXEC_DE_LOAD_16_PARAM; end else begin next_state=`EXEC_DE_LOAD_8_PARAM; end in_alu_sel1=2'b00; /* PARAM1 */ ALU_OP=`ALU_OP_AND; case(IN_MOD) 3'b011:begin in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; end default:begin `invalid_instruction end endcase OUT_MOD=3'b100;/*NULL*/ `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1010_100?_???:begin /* TEST - Bitwise AND of immediate and accumulator affecting only flags */ /* 1 0 1 0 1 0 0 W | DATA | DATA if W | */ opcode_size=0; Wbit=CIR[8:8]; IN_MOD=3'b011; RM=3'b000; MEM_OR_IO=0; if(Wbit==1)begin next_state=`EXEC_DE_LOAD_16_PARAM; end else begin next_state=`EXEC_DE_LOAD_8_PARAM; end in_alu_sel1=2'b00; /* PARAM1 */ ALU_OP=`ALU_OP_AND; in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; OUT_MOD=3'b100;/*NULL*/ `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b0101_1???_???:begin /* POP - REG=[SP]; SP+=2 */ /* | 0 1 0 1 1 REG | */ opcode_size=0; Wbit=1; Sbit=0; PARAM1=2; reg_write_addr={1'b1,CIR[10:8]}; seq_addr_entry<=`UCODE_POP_ENTRY; `normal_microcoded DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1111_1111_100:begin /* JMP - Unconditional indirect within segment jump */ /* 1 1 1 1 1 1 1 1 | MOD 1 0 0 R/M | < DISP-LO > | < DISP-HI > */ opcode_size=1; Wbit=1; IN_MOD={1'b0,CIR[7:6]}; RM=CIR[2:0]; MEM_OR_IO=0; in_alu_sel1=2'b11; if (IN_MOD==3'b011)begin in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; next_state=`EXEC_WRITE_ENTRY; end else begin in_alu_sel2=2'b00; next_state=`EXEC_MEMIO_READ; end ALU_OP=`ALU_OP_ADD; OUT_MOD=3'b101; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1100_011?_000:begin /* MOV - Move immediate to register/memory */ /* 1 1 0 0 0 1 1 W | MOD 0 0 0 R/M | < DISP-LO > | < DISP-HI > | DATA | DATA if W */ Wbit=CIR[8:8]; opcode_size=1; in_alu_sel1=2'b00; in_alu_sel2=2'b11; MEM_OR_IO=0; if(Wbit==1)begin next_state=`EXEC_DE_LOAD_16_PARAM; end else begin next_state=`EXEC_DE_LOAD_8_PARAM; end OUT_MOD={1'b0,CIR[7:6]}; IN_MOD=3'b011; RM=CIR[2:0]; `normal_instruction; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1100_1101_???:begin /* INT - execute interrupt handler */ /* 1 1 0 0 1 1 0 1 | DATA |*/ // [skipped] 1) push flags // [skipped] 2) clear trap and interrupt enable flag // [skipped] 3) push CS // [skipped] 4) fetch CS from interrupt table // 5) push ProgCount // 6) fetch ProgCount from interrupt table opcode_size=0; Wbit=1; Sbit=0; PARAM2=2; seq_addr_entry<=`UCODE_INT_ENTRY; `normal_microcoded DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1110_011?_???:begin /* OUT - write AL or AX to a defined output port */ /* | 1 1 1 0 0 1 1 W | DATA 8 | */ memio_address_select=1; Wbit=CIR[8:8]; opcode_size=0; in_alu_sel1=2'b00; in_alu_sel2=2'b11; reg_read_port1_addr={Wbit,3'b000}; next_state=`EXEC_DE_LOAD_8_PARAM; MEM_OR_IO=1; HALT <= 0; PARAM1=0; OUT_MOD={3'b000}; DEPENDS_ON_PREVIOUS<=0; IN_MOD=3'b011; end 11'b1100_1111_???:begin /* IRET - Return from interrupt */ /* | 1 1 0 0 1 1 1 1 | */ // Since we only push one thing on the stack // on INT we can just reuse the code from RET opcode_size=0; Wbit=1; Sbit=0; PARAM1=2; seq_addr_entry<=`UCODE_RET_ENTRY; `normal_microcoded DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; end 11'b1000_000?_100,11'b1000_000?_001:begin /* OR - Bitwise OR immediate and register/mem */ /* 1 0 0 0 0 0 0 W | MOD 0 0 1 R/M | < DISP-LO > | < DISP-HI > | DATA | DATA if W */ /* AND - Bitwise AND immediate and register/mem */ /* 1 0 0 0 0 0 0 W | MOD 1 0 0 R/M | < DISP-LO > | < DISP-HI > | DATA | DATA if W */ opcode_size=1; Wbit=CIR[8:8]; IN_MOD={1'b0,CIR[7:6]}; RM={CIR[2:0]}; MEM_OR_IO=0; if(Wbit==1)begin next_state=`EXEC_DE_LOAD_16_PARAM; end else begin next_state=`EXEC_DE_LOAD_8_PARAM; end in_alu_sel1=2'b00; /* PARAM1 */ case(CIR[5:3]) 3'b100: ALU_OP=`ALU_OP_AND; 3'b001: ALU_OP=`ALU_OP_OR; default:begin end endcase case(IN_MOD) 3'b011:begin in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; reg_write_addr={Wbit,RM}; end default:begin `unimpl_addressing_mode end endcase OUT_MOD=IN_MOD; DEPENDS_ON_PREVIOUS<=0; memio_address_select=0; `normal_instruction; end 11'b0000_00??_???:begin /* ADD - Reg/memory with register to either */ /* 0 0 0 0 0 0 D W | MOD REG R/M | < DISP LO > | < DISP HI > | */ opcode_size=1; Wbit=CIR[8:8]; Sbit=0; OUT_MOD={1'b0,CIR[7:6]}; IN_MOD=3'b011; RM=CIR[2:0]; in_alu_sel1=2'b01;//constantly register reg_read_port1_addr={Wbit,CIR[5:3]}; if(IN_MOD==3'b011)begin in_alu_sel2=2'b01; reg_read_port2_addr={Wbit,RM}; reg_write_addr={Wbit,RM}; next_state=`EXEC_WRITE_ENTRY; end else begin in_alu_sel2=2'b00; if(Wbit) next_state=`EXEC_DE_LOAD_16_PARAM; else next_state=`EXEC_DE_LOAD_8_PARAM; end MEM_OR_IO=0; memio_address_select=0; ALU_OP=`ALU_OP_ADD; DEPENDS_ON_PREVIOUS<=0; `normal_instruction; end default:begin `invalid_instruction end endcase end else begin /*Microcode output*/ //Sbit, Wbit, opcode_size and the others are still latched //from when we ordered the switch to microcode seq_addr_entry <= ucode_data[`UCODE_ADDR_BITS-1:0]; case(ucode_data[8:6]) 3'b000: next_state=`EXEC_WRITE_ENTRY; 3'b001: next_state=`EXEC_DE_LOAD_16_PARAM; 3'b010: next_state=`EXEC_DE_LOAD_8_PARAM; 3'b011: next_state=`EXEC_MEMIO_READ; 3'b100: next_state=`EXEC_MEMIO_READ_SETADDR; default: begin end /*impossible*/ endcase if(ucode_data[36:36]==0) /*Set reg write address*/ reg_write_addr = ucode_data[12:9 ]; in_alu_sel1 = ucode_data[14:13]; in_alu_sel2 = ucode_data[16:15]; OUT_MOD = ucode_data[19:17]; /*1:1 map essentially but I want to keep the spec for these bits separate * from the alu op select bits*/ case(ucode_data[22:20]) 3'b000: ALU_OP=`ALU_OP_ADD; 3'b001: ALU_OP=`ALU_OP_SUB; 3'b010: ALU_OP=`ALU_OP_AND; 3'b011: ALU_OP=`ALU_OP_OR; 3'b100: ALU_OP=`ALU_OP_XOR; 3'b101: ALU_OP=`ALU_OP_ADD_SIGNED_B; 3'b110: ALU_OP=`ALU_OP_SUB_REVERSE; 3'b111: ALU_OP=`ALU_OP_SHIFT_LEFT; default: begin end endcase if(ucode_data[34:34]==0) /* Set reg read port 1 address */ reg_read_port1_addr=ucode_data[26:23]; IN_MOD=ucode_data[29:27]; if(ucode_data[35:35]==0) /* Set reg read port 1 address */ reg_read_port2_addr=ucode_data[33:30]; if(ucode_data[37:37]==1) /* Overwrite Wbit */ Wbit=ucode_data[38:38]; memio_address_select=ucode_data[39:39]; MEM_OR_IO=0; HALT <= 0; end end `undef invalid_instruction endmodule // verilator lint_on BLKSEQ /* IN: {CIR[15:8],CIR[5:3]} */ /* OUT: number in bytes */ module InstrSize ( input [10:0] IN, output reg [2:0] VERDICT ); always @( IN ) begin casez(IN) 11'b0000_010?_??? : VERDICT <= 3'd2+{2'b0,IN[3:3]}; /* ADD - Add Immediate word/byte to accumulator */ 11'b1000_00??_101 : VERDICT <= 3'd3+{2'b0,(IN[4:3]==2'b01)}; /* SUB - Subtract immediate word/byte from register/memory */ 11'b1000_00??_000 : VERDICT <= 3'd3+{2'b0,(IN[4:3]==2'b01)}; /* ADD - Add Immediate word/byte to register/memory */ 11'b1000_00??_111 : VERDICT <= 3'd3+{2'b0,(IN[4:3]==2'b01)}; /* CMP - compare Immediate with register / memory */ 11'b1011_????_??? : VERDICT <= 3'd2+{2'b0,IN[6:6]}; /* MOV - Move Immediate byte to register */ 11'b1000_10??_??? : VERDICT <= 3'd2; /* MOV - Reg/Mem to/from register */ 11'b0100_????_??? : VERDICT <= 3'd1; /* DEC - Decrement Register | INC - Increment Register */ 11'b1111_111?_00? : VERDICT <= 3'd2; /* INC - Register/Memory | DEC - Register/Memory */ 11'b1111_0100_??? : VERDICT <= 3'd1; /* HLT - Halt */ 11'b0011_110?_??? : VERDICT <= 3'd2+{2'b0,IN[3:3]}; /* CMP - Compare Immediate with accumulator */ 11'b0111_????_??? : VERDICT <= 3'd2; /* Conditional relative jumps ( JE/JZ, JS/JNS ... ) */ 11'b1110_1011_??? : VERDICT <= 3'd2; /* JMP - Unconditional jump direct within segment (short) */ 11'b1110_1000_??? : VERDICT <= 3'd3; /* CALL - Direct call within segment */ 11'b1100_0011_??? : VERDICT <= 3'd1; /* RET - Return from call within segment */ 11'b1010_101?_??? : VERDICT <= 3'd1; /* STOS - Write byte/word to [DI] and increment accordingly */ 11'b0101_0???_??? : VERDICT <= 3'd1; /* PUSH - SP-=2; [SP]=REG */ 11'b1111_011?_000 : VERDICT <= 3'd3+{2'b0,IN[3:3]}; /* TEST - Bitwise AND affecting only flags */ 11'b0101_1???_??? : VERDICT <= 3'd1; /* POP - REG=[SP]; SP+=2 */ 11'b1111_1111_100 : VERDICT <= 3'd2; /* JMP - Unconditional indirect within segment jump */ 11'b1100_011?_000 : VERDICT <= 3'd3+{2'b0,IN[3:3]}; /* MOV - Move immediate to register/memory */ 11'b1100_1101_??? : VERDICT <= 3'd2; /* INT - execute interrupt handler */ 11'b1110_011?_??? : VERDICT <= 3'd2; /* OUT - write AL or AX to a defined output port */ 11'b1100_1111_??? : VERDICT <= 3'd1; /* IRET - Return from interrupt */ 11'b1000_000?_100 : VERDICT <= 3'd3+{2'b0,IN[3:3]}; /* AND - Bitwise AND immediate and register/mem */ 11'b1000_000?_001 : VERDICT <= 3'd3+{2'b0,IN[3:3]}; /* OR - Bitwise OR immediate and register/mem */ 11'b1010_100?_??? : VERDICT <= 3'd2+{2'b0,IN[3:3]}; /* TEST - Bitwise AND affecting only flags */ 11'b0000_00??_??? : VERDICT <= 3'd2; /* ADD - Reg/memory with register to either */ default:begin end endcase end endmodule `ifdef INCLUDE_EARLY_CALC_CIRUIT module Is1 ( input [7:0] IN, output reg VERDICT ); always @( IN ) begin casez(IN) 8'b0100_???? : VERDICT <= 1; /* DEC - Decrement Register | INC - Increment Register */ 8'b1111_0100 : VERDICT <= 1; /* HLT - Halt */ 8'b1100_0011 : VERDICT <= 1; /* RET - Return from call within segment */ 8'b1010_101? : VERDICT <= 1; /* STOS - Write byte/word to [DI] and increment accordingly */ 8'b0101_0??? : VERDICT <= 1; /* PUSH - SP-=2; [SP]=REG */ 8'b0101_1??? : VERDICT <= 1; /* POP - REG=[SP]; SP+=2 */ 8'b1100_1111 : VERDICT <= 1; /* IRET - Return from interrupt */ default:begin VERDICT<= 0; end endcase end endmodule `endif `undef unimpl_addressing_mode