Fixed most problems verilator's linter found

This commit is contained in:
(Tim) Efthimis Kritikos 2023-03-04 06:22:28 +00:00
parent 59ec1b7a15
commit ba52ff89e6
7 changed files with 282 additions and 241 deletions

View File

@ -26,7 +26,7 @@ wire signed [7:0]SIGNED_8B;
assign SIGNED_B=B;
assign SIGNED_8B=B[7:0];
assign FLAGS={(Wbit==1)?OUT[15:15]:OUT[7:7],(Wbit==1) ? (OUT[15:0]=='h0000) : (OUT[7:0]=='h00),5'b00000,C_FLAG};
assign FLAGS={(Wbit==1)?OUT[15:15]:OUT[7:7],(Wbit==1) ? (OUT[15:0]=='h0000) : (OUT[7:0]=='h00),5'b0,C_FLAG};
always @ ( * ) begin
if(Wbit==1)begin
@ -35,9 +35,9 @@ always @ ( * ) begin
`ALU_OP_ADD_SIGNED_B: {C_FLAG,OUT}=A+SIGNED_B;
`ALU_OP_SUB: {C_FLAG,OUT}=A-B;
`ALU_OP_SUB_REVERSE: {C_FLAG,OUT}=B-A;
`ALU_OP_AND: OUT=A&B;
`ALU_OP_OR: OUT=A|B;
`ALU_OP_XOR: OUT=A^B;
`ALU_OP_AND: begin C_FLAG=0;OUT=A&B; end
`ALU_OP_OR: begin C_FLAG=0;OUT=A|B; end
`ALU_OP_XOR: begin C_FLAG=0;OUT=A^B; end
default:begin
OUT=0;
C_FLAG=0;
@ -49,9 +49,9 @@ always @ ( * ) begin
`ALU_OP_ADD_SIGNED_B: {C_FLAG,OUT[7:0]}=A[7:0]+SIGNED_8B;
`ALU_OP_SUB: {C_FLAG,OUT[7:0]}=A[7:0]-B[7:0];
`ALU_OP_SUB_REVERSE: {C_FLAG,OUT[7:0]}=B[7:0]-A[7:0];
`ALU_OP_AND: OUT=A&B;
`ALU_OP_OR: OUT=A|B;
`ALU_OP_XOR: OUT=A^B;
`ALU_OP_AND: begin C_FLAG=0;OUT=A&B; end
`ALU_OP_OR: begin C_FLAG=0;OUT=A|B; end
`ALU_OP_XOR: begin C_FLAG=0;OUT=A^B; end
default:begin
OUT=0;
C_FLAG=0;

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@ -29,19 +29,20 @@ module microcode(
initial begin
string ucode_path;
if($value$plusargs("MICROCODE=%s",ucode_path))begin
$readmemb(ucode_path,ucode,0,`UCODE_SIZE-1);
$readmemb(ucode_path,ucode_rom,0,`UCODE_SIZE-1);
end else begin
$display("Please supply microcode rom file as a runtime vvp argument +MICROCODE=<path>");
$finish;
end
end
reg [`UCODE_DATA_BITS-1:0] ucode [ 0:`UCODE_SIZE-1 ];
reg [`UCODE_DATA_BITS-1:0] ucode_rom [ 0:`UCODE_SIZE-1 ];
assign DATA=ucode[ADDR];
assign DATA=ucode_rom[ADDR];
endmodule
// verilator lint_off UNUSEDSIGNAL
module decoder(
input wire [15:0] CIR,input wire [15:0] FLAGS, output wire [2:0] INSTRUCTION_INFO, output wire [1:0]DECODER_SIGNALS,output reg [`PROC_STATE_BITS-1:0]next_state
,output reg [2:0]IN_MOD, output reg [2:0]RM, output reg [15:0] PARAM1,output reg [15:0] PARAM2
@ -51,6 +52,7 @@ module decoder(
,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 reg [2:0]instruction_size
);
// verilator lint_on UNUSEDSIGNAL
reg [3:0]reg_read_port1_addr;
reg [3:0]reg_read_port2_addr;
@ -66,23 +68,31 @@ assign DECODER_SIGNALS={ERROR,HALT};
// verilator lint_off UNUSEDSIGNAL
wire [`UCODE_DATA_BITS-1:0] ucode_data;
reg [`UCODE_ADDR_BITS-1:0] UCODE_ADDR;
// verilator lint_on UNUSEDSIGNAL
microcode ucode(seq_addr_input,ucode_data);
/* 0 0 0 0 0 0 0 0 | 0 0 0 0 0 0 0 0 | 0 0 0 0 0 0 0 0 | 0 0 0 0 0 0 0 0 */
`define invalid_instruction next_state=`PROC_IF_STATE_ENTRY;ERROR=1;IN_MOD=2'b11;
`define invalid_instruction next_state=`PROC_IF_STATE_ENTRY;ERROR<=1;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 PROC_DE_LOAD_8_PARAM
`define normal_instruction seq_addr_entry<=`UCODE_NO_INSTRUCTION;ERROR<=0;HALT<=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 @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
if (SIMPLE_MICRO==0)begin
ERROR=0;HALT=0;seq_addr_entry=`UCODE_NO_INSTRUCTION;
casex({CIR[15:8],CIR[5:3]})
11'b0000_010x_xxx : 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;
@ -92,7 +102,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
end else begin
instruction_size=2;
end
IN_MOD=2'b11;
IN_MOD=3'b011;
in_alu1_sel1=2'b00;
in_alu1_sel2=2'b01;
OUT_MOD=3'b011;
@ -103,9 +113,10 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
next_state=`PROC_DE_LOAD_16_PARAM;
else
next_state=`PROC_DE_LOAD_8_PARAM;
`normal_instruction;
end
11'b1000_00xx_101, /* SUB */
11'b1000_00xx_000 : /* ADD */ begin
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 */
@ -113,17 +124,17 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
opcode_size=1;
Wbit=CIR[8:8];
Sbit=CIR[9:9];
IN_MOD=CIR[7:6];
IN_MOD={1'b0,CIR[7:6]};
RM=CIR[2:0];
in_alu1_sel1=2'b00;
if(IN_MOD==2'b11)begin
if(IN_MOD==3'b011)begin
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,RM};
reg_write_addr={Wbit,RM};
end else begin
in_alu1_sel2=2'b00;
end
OUT_MOD={1'b0,IN_MOD};
OUT_MOD=IN_MOD;
case({Sbit,Wbit})
2'b00,2'b11:begin
next_state=`PROC_DE_LOAD_8_PARAM;
@ -145,14 +156,15 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
`invalid_instruction
end
endcase
`normal_instruction;
end
11'b1000_00xx_111 : begin
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=CIR[7:6];
IN_MOD={1'b0,CIR[7:6]};
RM=CIR[2:0];
case({Sbit,Wbit})
2'b00,2'b11:begin
@ -168,7 +180,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
in_alu1_sel1=2'b00;
OUT_MOD=3'b100;
ALU_1OP=`ALU_OP_SUB;
if(IN_MOD==2'b11)begin
if(IN_MOD==3'b011)begin
/*compare register with param*/
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,RM};
@ -179,14 +191,15 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
in_alu1_sel2=2'b00;
next_state=`PROC_DE_LOAD_16_PARAM; /*will the call MEMIO_READ*/
end
`normal_instruction;
end
11'b1011_0xxx_xxx : begin
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 */
instruction_size=2;
opcode_size=0;
IN_MOD=2'b11;
IN_MOD=3'b011;
in_alu1_sel1=2'b00;
in_alu1_sel2=2'b00;
OUT_MOD=3'b011;
@ -195,13 +208,14 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
PARAM2=0;
ALU_1OP=`ALU_OP_ADD;
next_state=`PROC_EX_STATE_ENTRY;
`normal_instruction;
end
11'b1011_1xxx_xxx : begin
11'b1011_1???_??? : begin
/*MOV - Move Immediate word to register*/
Wbit=CIR[11:11]; /*IS 1 */
instruction_size=3;
opcode_size=0;
IN_MOD=2'b11;
IN_MOD=3'b011;
in_alu1_sel1=2'b00;
in_alu1_sel2=2'b00;
OUT_MOD=3'b011;
@ -209,9 +223,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
ALU_1OP=`ALU_OP_ADD;
PARAM2=0;
next_state=`PROC_DE_LOAD_16_PARAM;
`normal_instruction;
end
11'b1000_10xx_xxx : begin
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;
@ -223,7 +237,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
if(CIR[9:9] == 1)begin
/* Mem/Reg to reg */
IN_MOD={1'b0,CIR[7:6]};
if(IN_MOD==2'b11)begin
if(IN_MOD==3'b011)begin
/*Reg to Reg*/
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,RM};
@ -239,7 +253,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
/* Reg to Mem/Reg */
IN_MOD=3'b011;
OUT_MOD={1'b0,CIR[7:6]};
if(IN_MOD==2'b11)begin
if(IN_MOD==3'b011)begin
/*Reg to Reg*/
in_alu1_sel2=2'b01;
reg_write_addr={Wbit,RM};
@ -251,10 +265,11 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
end
reg_read_port2_addr={Wbit,CIR[5:3]};
end
ALU_1OP=`ALU_OP_ADD;
`normal_instruction;
end
11'b0100_xxxx_xxx:begin//DEC
11'b0100_????_???:begin//DEC
/* DEC - Decrement Register */
/* | 0 1 0 0 1 REG | */
/* INC - Increment Register */
@ -265,7 +280,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
in_alu1_sel1=2'b01;
in_alu1_sel2=2'b00;
OUT_MOD=3'b011;
IN_MOD=2'b11;
IN_MOD=3'b011;
PARAM2=1;
reg_read_port1_addr={1'b1,CIR[10:8]};
reg_write_addr={1'b1,CIR[10:8]};
@ -274,8 +289,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
else
ALU_1OP=`ALU_OP_SUB;
next_state=`PROC_EX_STATE_ENTRY;
`normal_instruction;
end
11'b1111_111x_00x : begin
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 */
@ -283,33 +299,37 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
instruction_size=2;
opcode_size=1;
Wbit=CIR[8:8];
IN_MOD=CIR[7:6];
IN_MOD={1'b0,CIR[7:6]};
RM=CIR[2:0];
in_alu1_sel2=(IN_MOD==2'b11)? 2'b01 : 2'b00;
in_alu1_sel2=(IN_MOD==3'b011)? 2'b01 : 2'b00;
in_alu1_sel1=2'b00;/* number 1 */
PARAM1=1;
OUT_MOD={1'b0,IN_MOD};
OUT_MOD=IN_MOD;
/*in case IN_MOD=11 */
/*in case IN_MOD=011 */
reg_read_port2_addr={1'b0,RM};
reg_write_addr={1'b0,RM};
ALU_1OP=(CIR[3:3]==1)?`ALU_OP_SUB_REVERSE:`ALU_OP_ADD;
if ( IN_MOD == 2'b11 )
if ( IN_MOD == 3'b011 )
next_state=`PROC_EX_STATE_ENTRY;
else
next_state=`PROC_MEMIO_READ;
`normal_instruction;
end
11'b1111_0100_xxx : begin
11'b1111_0100_??? : begin
/* HLT - Halt */
/* 1 1 1 1 0 1 0 0 | */
instruction_size=1;
opcode_size=0;
IN_MOD=2'b11;
HALT=1;
IN_MOD=3'b011;
HALT<=1;
ERROR<=0;
seq_addr_entry<=`UCODE_NO_INSTRUCTION;
next_state=`PROC_HALT_STATE;
end
11'b0011_110x_xxx : begin
11'b0011_110?_??? : begin
/* CMP - Compare Immediate with accumulator */
/* 0 0 1 1 1 1 0 W | DATA | DATA if W |*/
/* */
@ -322,7 +342,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
end else begin
instruction_size=2;
end
IN_MOD=2'b11;
IN_MOD=3'b011;
in_alu1_sel1=2'b00;
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,3'b000};
@ -334,8 +354,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
PARAM1[7:0]=CIR[7:0];
next_state=`PROC_EX_STATE_ENTRY;
end
`normal_instruction;
end
11'b0111_xxxx_xxx:begin
11'b0111_????_???:begin
/* Conditional relative jumps */
/* JE/JZ - Jump on Zero */
/* 0 1 1 1 0 1 0 0 | IP-INC8 |*/
@ -386,8 +407,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
`invalid_instruction; /*We don't support that condition*/
end
endcase
`normal_instruction;
end
11'b1110_1011_xxx:begin
11'b1110_1011_???:begin
/* JMP - Unconditional jump direct within segment (short) */
/* | 1 1 1 0 1 0 1 1 | IP-INC-LO | */
instruction_size=2;
@ -399,8 +421,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
ALU_1OP=`ALU_OP_ADD_SIGNED_B;
OUT_MOD=3'b101;
next_state=`PROC_EX_STATE_ENTRY;
`normal_instruction;
end
11'b1100_1101_xxx:begin
11'b1100_1101_???:begin
/* INT - execute interrupt handler */
/* 1 1 0 0 1 1 0 1 | DATA |*/
instruction_size=2;
@ -410,8 +433,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
$write("%s" ,register_file.registers[2][7:0]); /*TODO:Could trigger erroneously while CIR is not final*/
end
next_state=`PROC_IF_STATE_ENTRY;
`normal_instruction;
end
11'b1110_1000_xxx:begin
11'b1110_1000_???:begin
/* CALL - Direct call within segment */
/* 1 1 1 0 1 0 0 0 | IP-INC-LO | IP-INC-HI |*/
@ -421,9 +445,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
Wbit=1;
Sbit=1;
PARAM2=2; //subtract from sp
seq_addr_entry=`UCODE_CALL_ENTRY;
seq_addr_entry<=`UCODE_CALL_ENTRY;
end
11'b1100_0011_xxx:begin
11'b1100_0011_???:begin
/* RET - Return from call within segment */
/* | 1 1 0 0 0 0 1 1 | */
@ -433,20 +457,20 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
Wbit=1;
Sbit=0;
PARAM1=2;
seq_addr_entry=`UCODE_RET_ENTRY;
seq_addr_entry<=`UCODE_RET_ENTRY;
end
11'b1010_101x_xxx:begin
11'b1010_101?_???:begin
/* STOS - Write byte/word to [DI] and increment accordingly */
/* | 1 0 1 0 1 0 1 W | */
opcode_size=0;
instruction_size=1;
Wbit=CIR[8:8];
Sbit=0;
RM=101;
seq_addr_entry=`UCODE_STOS_ENTRY;
RM=3'b101;
seq_addr_entry<=`UCODE_STOS_ENTRY;
PARAM2=(Wbit==1)?2:1;
end
11'b0101_0xxx_xxx:begin
11'b0101_0???_???:begin
/* PUSH - SP-=2; [SP]=REG */
/* | 0 1 0 1 0 REG | */
opcode_size=0;
@ -455,9 +479,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
Sbit=0;
PARAM2=2;
reg_read_port2_addr={1'b1,CIR[10:8]};
seq_addr_entry=`UCODE_PUSH_ENTRY;
seq_addr_entry<=`UCODE_PUSH_ENTRY;
end
11'b1111_011x_000:begin
11'b1111_011?_000:begin
/* TEST - Bitwise AND 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;
@ -474,7 +498,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
in_alu1_sel1=2'b00; /* PARAM1 */
ALU_1OP=`ALU_OP_AND;
case(IN_MOD)
2'b11:begin
3'b011:begin
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,RM};
end
@ -483,8 +507,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
end
endcase
OUT_MOD=3'b100;/*NULL*/
`normal_instruction;
end
11'b0101_1xxx_xxx:begin
11'b0101_1???_???:begin
/* POP - REG=[SP]; SP+=2 */
/* | 0 1 0 1 1 REG | */
opcode_size=0;
@ -493,7 +518,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
Sbit=0;
PARAM1=2;
reg_write_addr={1'b1,CIR[10:8]};
seq_addr_entry=`UCODE_POP_ENTRY;
seq_addr_entry<=`UCODE_POP_ENTRY;
end
11'b1111_1111_100:begin
/* JMP - Unconditional indirect within segment jump */
@ -504,7 +529,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
IN_MOD={1'b0,CIR[7:6]};
RM=CIR[2:0];
in_alu1_sel1=2'b11;
if (IN_MOD==2'b11)begin
if (IN_MOD==3'b011)begin
in_alu1_sel2=2'b01;
reg_read_port2_addr={Wbit,RM};
next_state=`PROC_EX_STATE_ENTRY;
@ -514,8 +539,9 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
end
ALU_1OP=`ALU_OP_ADD;
OUT_MOD=3'b101;
`normal_instruction;
end
11'b1100_011x_000:begin
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];
@ -533,7 +559,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
OUT_MOD={1'b0,CIR[7:6]};
IN_MOD=3'b011;
RM=CIR[2:0];
`normal_instruction;
end
default:begin
`invalid_instruction
@ -543,7 +569,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) 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[5:0];
seq_addr_entry <= ucode_data[`UCODE_ADDR_BITS-1:0];
case(ucode_data[7:6])
2'b00: next_state=`PROC_EX_STATE_ENTRY;
2'b01: next_state=`PROC_DE_LOAD_16_PARAM;
@ -565,6 +591,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
3'b100: ALU_1OP=`ALU_OP_XOR;
3'b101: ALU_1OP=`ALU_OP_ADD_SIGNED_B;
3'b110: ALU_1OP=`ALU_OP_SUB_REVERSE;
default: begin end
endcase
if(ucode_data[33:33]==0)
reg_read_port1_addr=ucode_data[25:22];
@ -575,5 +602,7 @@ always @( CIR or SIMPLE_MICRO or seq_addr_input ) begin
Wbit=ucode_data[36:36];
end
end
`undef invalid_instruction
endmodule
// verilator lint_on BLKSEQ

View File

@ -60,3 +60,5 @@
`define PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT2 6'b110010
`define PROC_NEXT_MICROCODE 6'b111000
`define PROC_RESET 6'b111100

View File

@ -98,9 +98,9 @@ reg [15:0] CIR;
reg [15:0] PARAM1;
reg [15:0] PARAM2;
// verilator lint_off UNDRIVEN
reg [15:0] FLAGS;
reg [15:0] BYTE_WRITE_TEMP_REG;//we read 16bits here if we want to change just 8 and leave the rest
// verilator lint_on UNDRIVEN
//Architectural Register file
reg [3:0] reg_write_addr;
@ -129,10 +129,13 @@ register_file register_file(
);
reg [15:0] ProgCount;
wire ProgCount_next_opcode;
wire ProgCount_arg;
assign ProgCount_next_opcode=ProgCount+instruction_size;
assign ProgCount_arg=ProgCount+opcode_size+1;
// verilator lint_off UNUSEDSIGNAL
wire [15:0] ProgCount_next_opcode;
wire [15:0] ProgCount_arg;
assign ProgCount_next_opcode=ProgCount+{13'b0,instruction_size};
assign ProgCount_arg=ProgCount+{15'b0,opcode_size}+16'd1;
// verilator lint_on UNUSEDSIGNAL
/*############ ALU / Execution units ########################################################## */
// ALU 1
@ -146,7 +149,7 @@ mux4 #(.WIDTH(16)) MUX16_1A(
/*0*/ PARAM1,
/*1*/ reg_read_port1_data,
/*2*/ ProgCount[15:0],
/*3*/ 16'b0000000000000000, /*0 Constant*/
/*3*/ 16'd0, /*0 Constant*/
in_alu1_sel1,
ALU_1A);
@ -154,7 +157,7 @@ mux4 #(.WIDTH(16)) MUX16_1B(
/*0*/ PARAM2,
/*1*/ reg_read_port2_data,
/*2*/ ProgCount[15:0],
/*3*/ 16'b0000000000000000, /*0 Constant*/
/*3*/ 16'd0, /*0 Constant*/
in_alu1_sel2,
ALU_1B);
@ -175,29 +178,31 @@ ALU ALU1(
/*############ Processor state machine ########################################################## */
/*** RESET LOGIC ***/
/* verilator lint_off MULTIDRIVEN */
always @(negedge reset) begin
if (reset==0) begin
@(posedge clock);
state=`PROC_HALT_STATE;
ucode_seq_addr=`UCODE_NO_INSTRUCTION;
ProgCount=0;//TODO: Reset Vector
HALT=0;
reg_write_we=1;
IOMEM=0;
@(posedge reset)
@(negedge clock);
state=`PROC_IF_STATE_ENTRY;
ERROR=0;
SIMPLE_MICRO=0;
instruction_size_init=1;
state <= `PROC_HALT_STATE; //TODO: race condition ??
end
always @(posedge reset) begin
state <= `PROC_RESET;
end
/* verilator lint_on MULTIDRIVEN */
/*** Processor stages ***/
`define invalid_instruction state=`PROC_IF_STATE_ENTRY;ERROR=1;
`define invalid_instruction state <= `PROC_IF_STATE_ENTRY;ERROR <= 1;
always @(posedge clock) begin
case(state)
`PROC_RESET:begin
ucode_seq_addr <= `UCODE_NO_INSTRUCTION;
ProgCount <= 0;//TODO: Reset Vector
HALT <= 0;
ERROR <= 0;
IOMEM <= 0;
SIMPLE_MICRO <= 0;
reg_write_we <= 1;
instruction_size_init <= 1;
state <= `PROC_IF_STATE_ENTRY;
end
`PROC_HALT_STATE:begin
end
`PROC_IF_STATE_ENTRY:begin
@ -213,13 +218,13 @@ always @(posedge clock) begin
$display("Fetched instruction at %0x",ProgCount - 0);
end
`endif
BHE = 0;
external_address_bus = ProgCount;
read = 0;
write = 1;
reg_write_we=1;
state=`PROC_IF_WRITE_CIR;
reg_write_in_sel=2'b00;
BHE <= 0;
external_address_bus <= {4'b0,ProgCount};
read <= 0;
write <= 1;
reg_write_we <= 1;
state <= `PROC_IF_WRITE_CIR;
reg_write_in_sel <= 2'b00;
end
`PROC_IF_WRITE_CIR:begin
/*I built the entire decode stage with CIR
@ -227,40 +232,40 @@ always @(posedge clock) begin
if(instruction_size==1)begin
/*Half on CIR half on this address */
state=`PROC_DE_STATE_ENTRY;
state <= `PROC_DE_STATE_ENTRY;
if(ProgCount[0:0]==1)begin
CIR = {CIR[7:0],external_data_bus[15:8]};
CIR <= {CIR[7:0],external_data_bus[15:8]};
end else begin
CIR = {CIR[7:0],external_data_bus[7:0]};
CIR <= {CIR[7:0],external_data_bus[7:0]};
end
ProgCount=ProgCount+1;
ProgCount <= ProgCount+1;
end else begin
if(ProgCount[0:0]==1)begin
/* Half on this address half on the next*/
ProgCount=ProgCount+1;
ProgCount <= ProgCount+1;
CIR[15:8] <= external_data_bus[15:8];
state=`PROC_IF_STATE_EXTRA_FETCH_SET;
state <= `PROC_IF_STATE_EXTRA_FETCH_SET;
end else begin
/* Both on this address! */
ProgCount=ProgCount+2;
ProgCount <= ProgCount+2;
CIR <= {external_data_bus[7:0],external_data_bus[15:8]};
state=`PROC_DE_STATE_ENTRY;
state <= `PROC_DE_STATE_ENTRY;
end
end
end
`PROC_IF_STATE_EXTRA_FETCH_SET:begin
external_address_bus = ProgCount;
BHE=0;
state=`PROC_IF_STATE_EXTRA_FETCH;
external_address_bus <= {4'b0,ProgCount};
BHE <= 0;
state <= `PROC_IF_STATE_EXTRA_FETCH;
end
`PROC_IF_STATE_EXTRA_FETCH:begin
CIR[7:0] <= external_data_bus[7:0];
ProgCount=ProgCount+1;
state=`PROC_DE_STATE_ENTRY;
ProgCount <= ProgCount+1;
state <= `PROC_DE_STATE_ENTRY;
end
`PROC_DE_STATE_ENTRY:begin
external_address_bus = ProgCount;
external_address_bus <= {4'b0,ProgCount};
if(SIMPLE_MICRO==0)begin
/*This flag is set at reset and jump because
* at IF we need to know the size of the
@ -269,110 +274,110 @@ always @(posedge clock) begin
* incorrect in both cases. So when it gets
* set reset it only at the start of the next
* 8086 instruction */
instruction_size_init=0;
instruction_size_init <= 0;
/* We cannot set these directly within
* microcode so don't overwrite useful values
* each time the next microcode is executed.
* Note this still allows to set initial values
* at the start of the microcode */
PARAM1=DE_PARAM1;
PARAM2=DE_PARAM2;
PARAM1 <= DE_PARAM1;
PARAM2 <= DE_PARAM2;
end
ERROR=DE_ERROR;
HALT=DE_HALT;
reg_read_port1_addr=DE_reg_read_port1_addr;
reg_read_port2_addr=DE_reg_read_port2_addr;
reg_write_addr=DE_reg_write_addr;
ERROR <= DE_ERROR;
HALT <= DE_HALT;
reg_read_port1_addr <= DE_reg_read_port1_addr;
reg_read_port2_addr <= DE_reg_read_port2_addr;
reg_write_addr <= DE_reg_write_addr;
if ( (ucode_seq_addr==`UCODE_NO_INSTRUCTION) && (ucode_seq_addr_entry!=`UCODE_NO_INSTRUCTION) )begin
/*switch to microcode decoding*/
ucode_seq_addr=ucode_seq_addr_entry;
SIMPLE_MICRO=1;
ucode_seq_addr <= ucode_seq_addr_entry;
SIMPLE_MICRO <= 1;
/*keep state the same and rerun decode this time with all the data from the microcode rom*/
end else begin
state=next_state;
state <= next_state;
end
end
`PROC_DE_LOAD_REG_TO_PARAM:begin
PARAM2=reg_read_port2_data;
PARAM2<=reg_read_port2_data;
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end
`PROC_DE_LOAD_8_PARAM:begin
if(opcode_size==0)begin
if({Sbit,Wbit}==2'b11)begin
/*signed "16bit" read*/
PARAM1 = {{8{CIR[7:7]}},CIR[7:0]};
PARAM1 <= {{8{CIR[7:7]}},CIR[7:0]};
end else begin
PARAM1[7:0] = CIR[7:0];
PARAM1[7:0] <= CIR[7:0];
end
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end else begin
if(ProgCount[0:0]==1)begin
if({Sbit,Wbit}==2'b11)begin
/*signed "16bit" read*/
PARAM1 = {{8{external_data_bus[15:15]}},external_data_bus[15:8]};
PARAM1 <= {{8{external_data_bus[15:15]}},external_data_bus[15:8]};
end else begin
PARAM1[7:0] = external_data_bus[15:8];
PARAM1[7:0] <= external_data_bus[15:8];
end
end else begin
if({Sbit,Wbit}==2'b11)begin
/*signed "16bit" read*/
PARAM1 = {{8{external_data_bus[7:7]}},external_data_bus[7:0]};
PARAM1 <= {{8{external_data_bus[7:7]}},external_data_bus[7:0]};
end else begin
PARAM1[7:0] = external_data_bus[7:0];
PARAM1[7:0] <= external_data_bus[7:0];
end
end
ProgCount=ProgCount+1;
ProgCount <= ProgCount+1;
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end
end
`PROC_DE_LOAD_16_PARAM:begin
if(opcode_size==0)begin
PARAM1[7:0] = CIR[7:0];
PARAM1[7:0] <= CIR[7:0];
if(ProgCount[0:0]==1)begin
PARAM1[15:8] = external_data_bus[15:8];
PARAM1[15:8] <= external_data_bus[15:8];
end else begin
PARAM1[15:8] = external_data_bus[7:0];
PARAM1[15:8] <= external_data_bus[7:0];
end
ProgCount=ProgCount+1;
ProgCount <= ProgCount+1;
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end else begin
if(ProgCount[0:0]==1)begin
ProgCount=ProgCount+1;
PARAM1[7:0] = external_data_bus[15:8];
state=`PROC_DE_LOAD_16_EXTRA_FETCH_SET;
ProgCount <= ProgCount+1;
PARAM1[7:0] <= external_data_bus[15:8];
state <= `PROC_DE_LOAD_16_EXTRA_FETCH_SET;
end else begin
PARAM1 = external_data_bus;
ProgCount=ProgCount+2;
PARAM1 <= external_data_bus;
ProgCount <= ProgCount+2;
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end
end
end
`PROC_DE_LOAD_16_EXTRA_FETCH_SET:begin
external_address_bus = ProgCount;
state=`PROC_DE_LOAD_16_EXTRA_FETCH;
external_address_bus <= {4'b0,ProgCount};
state <= `PROC_DE_LOAD_16_EXTRA_FETCH;
end
`PROC_DE_LOAD_16_EXTRA_FETCH:begin
ProgCount=ProgCount+1;
PARAM1[15:8] = external_data_bus[7:0];
ProgCount <= ProgCount+1;
PARAM1[15:8] <= external_data_bus[7:0];
case(IN_MOD)
3'b000,3'b001,3'b010: state=`PROC_MEMIO_READ;
default: state=`PROC_EX_STATE_ENTRY;
3'b000,3'b001,3'b010: state <= `PROC_MEMIO_READ;
default: state <= `PROC_EX_STATE_ENTRY;
endcase
end
`PROC_MEMIO_READ:begin
@ -400,13 +405,13 @@ always @(posedge clock) begin
end
3'b100:begin
/*[SI]*/
reg_read_port1_addr=4'b1110;
state=`PROC_MEMIO_READ_SETADDR;
reg_read_port1_addr <= 4'b1110;
state <= `PROC_MEMIO_READ_SETADDR;
end
3'b101:begin
/*[DI]*/
reg_read_port1_addr=4'b1111;
state=`PROC_MEMIO_READ_SETADDR;
reg_read_port1_addr <= 4'b1111;
state <= `PROC_MEMIO_READ_SETADDR;
end
3'b110:begin
/*d16 */
@ -414,8 +419,8 @@ always @(posedge clock) begin
end
3'b111:begin
/*[BX]*/
reg_read_port1_addr=4'b1011;
state=`PROC_MEMIO_READ_SETADDR;
reg_read_port1_addr <= 4'b1011;
state <= `PROC_MEMIO_READ_SETADDR;
end
endcase
if(IN_MOD!=3'b000)begin
@ -424,8 +429,8 @@ always @(posedge clock) begin
end
end
3'b110:begin /* SP Indirect read*/
reg_read_port1_addr=4'b1100;
state=`PROC_MEMIO_READ_SETADDR;
reg_read_port1_addr <= 4'b1100;
state <= `PROC_MEMIO_READ_SETADDR;
end
default:begin
`invalid_instruction
@ -433,32 +438,32 @@ always @(posedge clock) begin
endcase
end
`PROC_MEMIO_READ_SETADDR:begin
external_address_bus = {5'b0000,reg_read_port1_data[15:0]};
state=reg_read_port1_data[0:0]?`PROC_MEMIO_GET_UNALIGNED_DATA:`PROC_MEMIO_GET_ALIGNED_DATA;
external_address_bus <= {4'b0,reg_read_port1_data[15:0]};
state <= reg_read_port1_data[0:0]?`PROC_MEMIO_GET_UNALIGNED_DATA:`PROC_MEMIO_GET_ALIGNED_DATA;
end
`PROC_MEMIO_GET_ALIGNED_DATA:begin
PARAM2=(Wbit==1)? external_data_bus : {8'b00000000,external_data_bus[7:0]} ;
state=`PROC_EX_STATE_ENTRY;
PARAM2 <= (Wbit==1)? external_data_bus : {8'b0,external_data_bus[7:0]} ;
state <= `PROC_EX_STATE_ENTRY;
end
`PROC_MEMIO_GET_UNALIGNED_DATA:begin
PARAM2={8'b00000000,external_data_bus[15:8]};
PARAM2 <= {8'b0,external_data_bus[15:8]};
if(Wbit==1) begin
state=`PROC_MEMIO_GET_SECOND_BYTE;
state <= `PROC_MEMIO_GET_SECOND_BYTE;
end else begin
state=`PROC_EX_STATE_ENTRY;
state <= `PROC_EX_STATE_ENTRY;
end
end
`PROC_MEMIO_GET_SECOND_BYTE:begin
external_address_bus=external_address_bus+1;
state=`PROC_MEMIO_GET_SECOND_BYTE1;
external_address_bus <= external_address_bus+1;
state <= `PROC_MEMIO_GET_SECOND_BYTE1;
end
`PROC_MEMIO_GET_SECOND_BYTE1:begin
PARAM2[15:8]=external_data_bus[7:0];
state=`PROC_EX_STATE_ENTRY;
PARAM2[15:8] <= external_data_bus[7:0];
state <= `PROC_EX_STATE_ENTRY;
end
`PROC_EX_STATE_ENTRY:begin
external_address_bus = ProgCount;
FLAGS[7:0] = ALU_1FLAGS[7:0];
external_address_bus <= {4'b0,ProgCount};
FLAGS[7:0] <= ALU_1FLAGS[7:0];
case(OUT_MOD)
3'b000,
3'b001,
@ -482,13 +487,13 @@ always @(posedge clock) begin
end
3'b100:begin
/*[SI]*/
reg_read_port1_addr=4'b1110;
state=`PROC_MEMIO_WRITE;
reg_read_port1_addr <= 4'b1110;
state <= `PROC_MEMIO_WRITE;
end
3'b101:begin
/*[DI]*/
reg_read_port1_addr=4'b1111;
state=`PROC_MEMIO_WRITE;
reg_read_port1_addr <= 4'b1111;
state <= `PROC_MEMIO_WRITE;
end
3'b110:begin
/*d16 */
@ -496,35 +501,35 @@ always @(posedge clock) begin
end
3'b111:begin
/*[BX]*/
reg_read_port1_addr=4'b1011;
state=`PROC_MEMIO_WRITE;
reg_read_port1_addr <= 4'b1011;
state <= `PROC_MEMIO_WRITE;
end
endcase
end
3'b011:begin
reg_write_we=0;
reg_write_we <= 0;
if (ucode_seq_addr==`UCODE_NO_INSTRUCTION)
state=`PROC_IF_STATE_ENTRY;
state <= `PROC_IF_STATE_ENTRY;
else
state=`PROC_NEXT_MICROCODE;
state <= `PROC_NEXT_MICROCODE;
end
3'b100:begin /*No output*/
if (ucode_seq_addr==`UCODE_NO_INSTRUCTION)
state=`PROC_IF_STATE_ENTRY;
state <= `PROC_IF_STATE_ENTRY;
else
state=`PROC_NEXT_MICROCODE;
state <= `PROC_NEXT_MICROCODE;
end
3'b101:begin /* Program Counter*/
ProgCount={5'b0000,ALU_1O[15:0]};
instruction_size_init=1;
ProgCount <= ALU_1O[15:0];
instruction_size_init <= 1;
if (ucode_seq_addr==`UCODE_NO_INSTRUCTION)
state=`PROC_IF_STATE_ENTRY;
state <= `PROC_IF_STATE_ENTRY;
else
state=`PROC_NEXT_MICROCODE;
state <= `PROC_NEXT_MICROCODE;
end
3'b110:begin /* SP Indirect write*/
reg_read_port1_addr=4'b1100;
state=`PROC_MEMIO_WRITE;
reg_read_port1_addr <= 4'b1100;
state <= `PROC_MEMIO_WRITE;
end
default:begin
`invalid_instruction
@ -536,65 +541,66 @@ always @(posedge clock) begin
`ifdef DEBUG_MEMORY_WRITES
$display("Writing at %04x , %04x",reg_read_port1_data,ALU_1O);
`endif
external_address_bus = {5'b0000,reg_read_port1_data[15:0]};
state = (Wbit==0) ? `PROC_MEMIO_PUT_BYTE : (reg_read_port1_data[0:0]?`PROC_MEMIO_PUT_UNALIGNED_16BIT_DATA:`PROC_MEMIO_PUT_ALIGNED_16BIT_DATA) ;
external_address_bus <= {4'b0,reg_read_port1_data[15:0]};
state <= (Wbit==0) ? `PROC_MEMIO_PUT_BYTE : (reg_read_port1_data[0:0]?`PROC_MEMIO_PUT_UNALIGNED_16BIT_DATA:`PROC_MEMIO_PUT_ALIGNED_16BIT_DATA) ;
end
`PROC_MEMIO_PUT_UNALIGNED_16BIT_DATA:begin
read=1;
BHE=0;
data_bus_output_register={ALU_1O[7:0],ALU_1O[15:8]};
state=`PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT;
read <= 1;
BHE <= 0;
data_bus_output_register <= {ALU_1O[7:0],ALU_1O[15:8]};
state <= `PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT;
end
`PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT:begin
write=0;
state=`PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT2;
write <= 0;
state <= `PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT2;
end
`PROC_MEMIO_PUT_UNALIGNED_PREP_NEXT2:begin
write=1;
external_address_bus=external_address_bus+1;
BHE=1;
state=`PROC_MEMIO_WRITE_EXIT;
write <= 1;
external_address_bus <= external_address_bus+1;
BHE <= 1;
state <= `PROC_MEMIO_WRITE_EXIT;
end
`PROC_MEMIO_PUT_ALIGNED_16BIT_DATA:begin
read=1;
data_bus_output_register={ALU_1O[15:8],ALU_1O[7:0]};
state=`PROC_MEMIO_WRITE_EXIT;
read <= 1;
data_bus_output_register <= {ALU_1O[15:8],ALU_1O[7:0]};
state <= `PROC_MEMIO_WRITE_EXIT;
end
`PROC_MEMIO_PUT_BYTE:begin
read=1;
state=`PROC_MEMIO_WRITE_EXIT;
read <= 1;
state <= `PROC_MEMIO_WRITE_EXIT;
if(reg_read_port1_data[0:0]==0) begin
BHE=1;
data_bus_output_register={8'b0,ALU_1O[7:0]};
BHE <= 1;
data_bus_output_register <= {8'b0,ALU_1O[7:0]};
end else begin
data_bus_output_register={ALU_1O[7:0],8'b0};
data_bus_output_register <= {ALU_1O[7:0],8'b0};
end
end
`PROC_MEMIO_WRITE_EXIT:begin
write=0;
write <= 0;
if (ucode_seq_addr==`UCODE_NO_INSTRUCTION)
state=`PROC_IF_STATE_ENTRY;
state <= `PROC_IF_STATE_ENTRY;
else
state=`PROC_NEXT_MICROCODE;
state <= `PROC_NEXT_MICROCODE;
end
`PROC_NEXT_MICROCODE:begin
read=0;
write=1; // maybe we are coming from MEMIO_WRITE
BHE=0;
ucode_seq_addr=ucode_seq_addr_entry; /*Reused for next address*/
if( ucode_seq_addr == `UCODE_NO_INSTRUCTION )begin
read <= 0;
write <= 1; // maybe we are coming from MEMIO_WRITE
BHE <= 0;
ucode_seq_addr <= ucode_seq_addr_entry; /*Reused for next address*/
if( ucode_seq_addr_entry == `UCODE_NO_INSTRUCTION )begin
/*Finished microcode*/
SIMPLE_MICRO=0;
state=`PROC_IF_STATE_ENTRY;
SIMPLE_MICRO <= 0;
state <= `PROC_IF_STATE_ENTRY;
end else begin
state=`PROC_DE_STATE_ENTRY;
state <= `PROC_DE_STATE_ENTRY;
end
reg_write_we=1;
reg_write_we <= 1;
end
default:begin
end
endcase
end
`undef invalid_instruction
endmodule

View File

@ -34,11 +34,11 @@ reg [15:0] registers [7:0];
assign read_port1_data[15:8] = read_port1_addr[3:3] ? registers[read_port1_addr[2:0]][15:8] : 8'hz ;
assign read_port1_data[7:0] = ( read_port1_addr[3:3] ? registers[read_port1_addr[2:0]][7:0] :
( read_port1_addr[2:2] ? {8'b0,registers[read_port1_addr[1:0]][15:8]} : {8'b0,registers[read_port1_addr[1:0]][7:0]} ) );
( read_port1_addr[2:2] ? registers[ {1'b0,read_port1_addr[1:0]} ][15:8] : registers[ {1'b0,read_port1_addr[1:0]} ][7:0] ) );
assign read_port2_data[15:8] = read_port2_addr[3:3] ? registers[read_port2_addr[2:0]][15:8] : 8'hz ;
assign read_port2_data[7:0] = ( read_port2_addr[3:3] ? registers[read_port2_addr[2:0]][7:0] :
( read_port2_addr[2:2] ? {8'b0,registers[read_port2_addr[1:0]][15:8]} : {8'b0,registers[read_port2_addr[1:0]][7:0]} ) );
( read_port2_addr[2:2] ? registers[ {1'b0,read_port2_addr[1:0]} ][15:8] : registers[ {1'b0,read_port2_addr[1:0]} ][7:0] ) );
`ifdef DEBUG_REG_WRITES
string debug_name;
@ -50,15 +50,15 @@ assign write_Wbit=write_port1_addr[3:3];
always @(negedge write_port1_we) begin
if(write_Wbit==1)begin
/* Word : AX,CX,DX,BX,SP,BP,SI,DI */
registers[write_port1_addr[2:0]]=write_port1_data;
registers[write_port1_addr[2:0]] <= write_port1_data;
end else begin
/* Byte : AL,CL,DL,BL,AX,CX,DX,BX */
if(write_port1_addr[2:2]==1)begin
/* Byte */
registers[write_port1_addr[1:0]][15:8]=write_port1_data[7:0];
registers[ {1'b0,write_port1_addr[1:0]} ][15:8] <= write_port1_data[7:0];
end else begin
/* Byte */
registers[write_port1_addr[1:0]][7:0]=write_port1_data[7:0];
registers[ {1'b0,write_port1_addr[1:0]} ][7:0] <= write_port1_data[7:0];
end
end

View File

@ -46,10 +46,12 @@ initial begin
$dumpfile(waveform_name);
$dumpvars(0,p,u1);
end
reset = 0;
clk_enable = 1;
#($random%500)
reset = 1;
#(`CPU_SPEED*2)
reset = 0;
#($random%1000)
#(`CPU_SPEED)
reset = 1;
end
@ -76,6 +78,8 @@ end
always @(posedge clock)begin
if(reset==1)
cycles=cycles+1;
else
cycles=0;
end
endmodule

View File

@ -17,14 +17,14 @@
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
`define UCODE_ADDR_BITS 5
`define UCODE_DATA_BITS 38
`define UCODE_SIZE 12
`define UCODE_DATA_BITS 38
`define UCODE_ADDR_BITS $clog2(`UCODE_SIZE)
/* DEFINE ADDRESSES IN THE MICROCODE */
`define UCODE_NO_INSTRUCTION 5'b00000
`define UCODE_CALL_ENTRY 5'b00001
`define UCODE_RET_ENTRY 5'b00100
`define UCODE_STOS_ENTRY 5'b00110
`define UCODE_PUSH_ENTRY 5'b01000
`define UCODE_POP_ENTRY 5'b01010
`define UCODE_NO_INSTRUCTION 4'b0000
`define UCODE_CALL_ENTRY 4'b0001
`define UCODE_RET_ENTRY 4'b0100
`define UCODE_STOS_ENTRY 4'b0110
`define UCODE_PUSH_ENTRY 4'b1000
`define UCODE_POP_ENTRY 4'b1010