-`define REG_A 0
-`define REG_B 1
-`define REG_C 2
-`define REG_D 3
-`define REG_E 4
-`define REG_F 5
-`define REG_H 6
-`define REG_L 7
-`define REG_SPH 8
-`define REG_SPL 9
-`define REG_PCH 10
-`define REG_PCL 11
-
-`define FLAG_Z 8'b10000000
-`define FLAG_N 8'b01000000
-`define FLAG_H 8'b00100000
-`define FLAG_C 8'b00010000
-
-`define STATE_FETCH 2'h0
-`define STATE_DECODE 2'h1
+`define REG_A 0
+`define REG_B 1
+`define REG_C 2
+`define REG_D 3
+`define REG_E 4
+`define REG_F 5
+`define REG_H 6
+`define REG_L 7
+`define REG_SPH 8
+`define REG_SPL 9
+`define REG_PCH 10
+`define REG_PCL 11
+
+`define _A registers[`REG_A]
+`define _B registers[`REG_B]
+`define _C registers[`REG_C]
+`define _D registers[`REG_D]
+`define _E registers[`REG_E]
+`define _F registers[`REG_F]
+`define _H registers[`REG_H]
+`define _L registers[`REG_L]
+`define _SPH registers[`REG_SPH]
+`define _SPL registers[`REG_SPL]
+`define _PCH registers[`REG_PCH]
+`define _PCL registers[`REG_PCL]
+`define _AF {`_A, `_F}
+`define _BC {`_B, `_C}
+`define _DE {`_D, `_E}
+`define _HL {`_H, `_L}
+`define _SP {`_SPH, `_SPL}
+`define _PC {`_PCH, `_PCL}
+
+`define FLAG_Z 8'b10000000
+`define FLAG_N 8'b01000000
+`define FLAG_H 8'b00100000
+`define FLAG_C 8'b00010000
+
+`define STATE_FETCH 2'h0
+`define STATE_DECODE 2'h1
`define STATE_EXECUTE 2'h2
`define STATE_WRITEBACK 2'h3
`define INSN_LD_reg_imm8 8'b00xxx110
-`define INSN_HALT 8'b01110110
+`define INSN_HALT 8'b01110110
`define INSN_LD_HL_reg 8'b01110xxx
`define INSN_LD_reg_HL 8'b01xxx110
`define INSN_LD_reg_reg 8'b01xxxxxx
`define INSN_LD_reg_imm16 8'b00xx0001
`define INSN_LD_SP_HL 8'b11111001
`define INSN_PUSH_reg 8'b11xx0101
-`define INSN_POP_reg 8'b11xx0001
-`define INSN_LDH_AC 8'b111x0010 // Either LDH A,(C) or LDH (C),A
-`define INSN_LDx_AHL 8'b001xx010 // LDD/LDI A,(HL) / (HL),A
-`define INSN_ALU8 8'b10xxxxxx // 10 xxx yyy
-`define INSN_NOP 8'b00000000
-`define INSN_RST 8'b11xxx111
-`define INSN_RET 8'b110x1001 // 1 = RETI, 0 = RET
-`define INSN_CALL 8'b11001101
+`define INSN_POP_reg 8'b11xx0001
+`define INSN_LDH_AC 8'b111x0010 // Either LDH A,(C) or LDH (C),A
+`define INSN_LDx_AHL 8'b001xx010 // LDD/LDI A,(HL) / (HL),A
+`define INSN_ALU8 8'b10xxxxxx // 10 xxx yyy
+`define INSN_ALU8IMM 8'b11xxx110
+`define INSN_NOP 8'b00000000
+`define INSN_RST 8'b11xxx111
+`define INSN_RET 8'b110x1001 // 1 = RETI, 0 = RET
+`define INSN_RETCC 8'b110xx000
+`define INSN_CALL 8'b11001101
+`define INSN_CALLCC 8'b110xx100 // Not that call/cc.
+`define INSN_JP_imm 8'b11000011
+`define INSN_JPCC_imm 8'b110xx010
+`define INSN_ALU_A 8'b00xxx111
+`define INSN_JP_HL 8'b11101001
+`define INSN_JR_imm 8'b00011000
+`define INSN_JRCC_imm 8'b001xx000
+`define INSN_INCDEC16 8'b00xxx011
+`define INSN_VOP_INTR 8'b11111100 // 0xFC is grabbed by the fetch if there is an interrupt pending.
+`define INSN_DI 8'b11110011
+`define INSN_EI 8'b11111011
+`define INSN_INCDEC_HL 8'b0011010x
+`define INSN_INCDEC_reg8 8'b00xxx10x
+`define INSN_LD8M_A 8'b111x0000 // 1111 for ld A, x; 1110 for ld x, A; bit 1 specifies 16m8 or 8m8
+`define INSN_LD16M_A 8'b111x1010 // 1111 for ld A, x; 1110 for ld x, A; bit 1 specifies 16m8 or 8m8
+
+`define INSN_cc_NZ 2'b00
+`define INSN_cc_Z 2'b01
+`define INSN_cc_NC 2'b10
+`define INSN_cc_C 2'b11
`define INSN_reg_A 3'b111
`define INSN_reg_B 3'b000
`define INSN_reg_E 3'b011
`define INSN_reg_H 3'b100
`define INSN_reg_L 3'b101
-`define INSN_reg_dHL 3'b110
-`define INSN_reg16_BC 2'b00
-`define INSN_reg16_DE 2'b01
-`define INSN_reg16_HL 2'b10
-`define INSN_reg16_SP 2'b11
-`define INSN_stack_AF 2'b11
-`define INSN_stack_BC 2'b00
-`define INSN_stack_DE 2'b01
-`define INSN_stack_HL 2'b10
+`define INSN_reg_dHL 3'b110
+`define INSN_reg16_BC 2'b00
+`define INSN_reg16_DE 2'b01
+`define INSN_reg16_HL 2'b10
+`define INSN_reg16_SP 2'b11
+`define INSN_stack_AF 2'b11
+`define INSN_stack_BC 2'b00
+`define INSN_stack_DE 2'b01
+`define INSN_stack_HL 2'b10
`define INSN_alu_ADD 3'b000
`define INSN_alu_ADC 3'b001
`define INSN_alu_SUB 3'b010
`define INSN_alu_XOR 3'b101
`define INSN_alu_OR 3'b110
`define INSN_alu_CP 3'b111 // Oh lawd, is dat some CP?
+`define INSN_alu_RLCA 3'b000
+`define INSN_alu_RRCA 3'b001
+`define INSN_alu_RLA 3'b010
+`define INSN_alu_RRA 3'b011
+`define INSN_alu_DAA 3'b100
+`define INSN_alu_CPL 3'b101
+`define INSN_alu_SCF 3'b110
+`define INSN_alu_CCF 3'b111
+
+`define EXEC_INC_PC `_PC <= `_PC + 1;
+`define EXEC_NEXTADDR_PCINC address <= `_PC + 1;
+`define EXEC_NEWCYCLE begin newcycle <= 1; rd <= 1; wr <= 0; end
+`define EXEC_WRITE(ad, da) begin address <= (ad); wdata <= (da); wr <= 1; end end
+`define EXEC_READ(ad) begin address <= (ad); rd <= 1; end end
module GBZ80Core(
input clk,
output reg [15:0] busaddress, /* BUS_* is latched on STATE_FETCH. */
inout [7:0] busdata,
- output reg buswr, output reg busrd);
+ output reg buswr, output reg busrd,
+ input irq, input [7:0] jaddr,
+ output reg [1:0] state);
- reg [1:0] state = 0; /* State within this bus cycle (see STATE_*). */
- reg [2:0] cycle = 0; /* Cycle for instructions. */
+// reg [1:0] state; /* State within this bus cycle (see STATE_*). */
+ reg [2:0] cycle; /* Cycle for instructions. */
reg [7:0] registers[11:0];
reg [7:0] opcode; /* Opcode from the current machine cycle. */
reg [7:0] rdata, wdata; /* Read data from this bus cycle, or write data for the next. */
- reg rd = 1, wr = 0, newcycle = 1;
+ reg rd, wr, newcycle;
reg [7:0] tmp, tmp2; /* Generic temporary regs. */
reg [7:0] buswdata;
assign busdata = buswr ? buswdata : 8'bzzzzzzzz;
- reg ie = 0;
+ reg ie, iedelay;
initial begin
registers[ 0] <= 0;
registers[ 9] <= 0;
registers[10] <= 0;
registers[11] <= 0;
- ie <= 0;
rd <= 1;
wr <= 0;
newcycle <= 1;
state <= 0;
cycle <= 0;
+ busrd <= 0;
+ buswr <= 0;
+ busaddress <= 0;
+ ie <= 0;
+ iedelay <= 0;
+ opcode <= 0;
+ state <= `STATE_WRITEBACK;
+ cycle <= 0;
end
always @(posedge clk)
end
`STATE_DECODE: begin
if (newcycle) begin
- opcode <= busdata;
+ if (ie && irq)
+ opcode <= `INSN_VOP_INTR;
+ else
+ opcode <= busdata;
rdata <= busdata;
newcycle <= 0;
cycle <= 0;
if (rd) rdata <= busdata;
cycle <= cycle + 1;
end
+ if (iedelay) begin
+ ie <= 1;
+ iedelay <= 0;
+ end
buswr <= 0;
busrd <= 0;
wr <= 0;
state <= `STATE_EXECUTE;
end
`STATE_EXECUTE: begin
-`define EXEC_INC_PC \
- {registers[`REG_PCH], registers[`REG_PCL]} <= {registers[`REG_PCH], registers[`REG_PCL]} + 1
-`define EXEC_NEXTADDR_PCINC \
- address <= {registers[`REG_PCH], registers[`REG_PCL]} + 1
-`define EXEC_NEWCYCLE \
- newcycle <= 1; rd <= 1; wr <= 0
casex (opcode)
- `INSN_LD_reg_imm8: begin
- case (cycle)
- 0: begin
- `EXEC_INC_PC;
- `EXEC_NEXTADDR_PCINC;
- rd <= 1;
- end
- 1: begin
- `EXEC_INC_PC;
- if (opcode[5:3] == `INSN_reg_dHL) begin
- address <= {registers[`REG_H], registers[`REG_L]};
- wdata <= rdata;
- rd <= 0;
- wr <= 1;
- end else begin
- `EXEC_NEWCYCLE;
- end
- end
- 2: begin
- `EXEC_NEWCYCLE;
- end
- endcase
- end
- `INSN_HALT: begin
- `EXEC_NEWCYCLE;
- /* XXX Interrupts needed for HALT. */
- end
- `INSN_LD_HL_reg: begin
- case (cycle)
- 0: begin
- case (opcode[2:0])
- `INSN_reg_A: wdata <= registers[`REG_A];
- `INSN_reg_B: wdata <= registers[`REG_B];
- `INSN_reg_C: wdata <= registers[`REG_C];
- `INSN_reg_D: wdata <= registers[`REG_D];
- `INSN_reg_E: wdata <= registers[`REG_E];
- `INSN_reg_H: wdata <= registers[`REG_H];
- `INSN_reg_L: wdata <= registers[`REG_L];
- endcase
- address <= {registers[`REG_H], registers[`REG_L]};
- wr <= 1; rd <= 0;
- end
- 1: begin
- `EXEC_INC_PC;
- `EXEC_NEWCYCLE;
- end
- endcase
- end
- `INSN_LD_reg_HL: begin
- case(cycle)
- 0: begin
- address <= {registers[`REG_H], registers[`REG_L]};
- rd <= 1;
- end
- 1: begin
- tmp <= rdata;
- `EXEC_INC_PC;
- `EXEC_NEWCYCLE;
- end
- endcase
- end
- `INSN_LD_reg_reg: begin
- `EXEC_INC_PC;
- `EXEC_NEWCYCLE;
- case (opcode[2:0])
- `INSN_reg_A: tmp <= registers[`REG_A];
- `INSN_reg_B: tmp <= registers[`REG_B];
- `INSN_reg_C: tmp <= registers[`REG_C];
- `INSN_reg_D: tmp <= registers[`REG_D];
- `INSN_reg_E: tmp <= registers[`REG_E];
- `INSN_reg_H: tmp <= registers[`REG_H];
- `INSN_reg_L: tmp <= registers[`REG_L];
- endcase
- end
- `INSN_LD_reg_imm16: begin
- `EXEC_INC_PC;
- case (cycle)
- 0: begin
- `EXEC_NEXTADDR_PCINC;
- rd <= 1;
- end
- 1: begin
- `EXEC_NEXTADDR_PCINC;
- rd <= 1;
- end
- 2: begin `EXEC_NEWCYCLE; end
- endcase
- end
- `INSN_LD_SP_HL: begin
- case (cycle)
- 0: begin
- tmp <= registers[`REG_H];
- end
- 1: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- tmp <= registers[`REG_L];
- end
- endcase
- end
- `INSN_PUSH_reg: begin /* PUSH is 16 cycles! */
- case (cycle)
- 0: begin
- wr <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
- case (opcode[5:4])
- `INSN_stack_AF: wdata <= registers[`REG_A];
- `INSN_stack_BC: wdata <= registers[`REG_B];
- `INSN_stack_DE: wdata <= registers[`REG_D];
- `INSN_stack_HL: wdata <= registers[`REG_H];
- endcase
- end
- 1: begin
- wr <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
- case (opcode[5:4])
- `INSN_stack_AF: wdata <= registers[`REG_F];
- `INSN_stack_BC: wdata <= registers[`REG_C];
- `INSN_stack_DE: wdata <= registers[`REG_E];
- `INSN_stack_HL: wdata <= registers[`REG_L];
- endcase
- end
- 2: begin /* TWIDDLE OUR FUCKING THUMBS! */ end
- 3: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- end
- endcase
- end
- `INSN_POP_reg: begin /* POP is 12 cycles! */
- case (cycle)
- 0: begin
- rd <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]};
- end
- 1: begin
- rd <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]};
- end
- 2: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- end
- endcase
- end
- `INSN_LDH_AC: begin
- case (cycle)
- 0: begin
- address <= {8'hFF,registers[`REG_C]};
- if (opcode[4]) begin // LD A,(C)
- rd <= 1;
- end else begin
- wr <= 1;
- wdata <= registers[`REG_A];
- end
- end
- 1: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- end
- endcase
- end
- `INSN_LDx_AHL: begin
- case (cycle)
- 0: begin
- address <= {registers[`REG_H],registers[`REG_L]};
- if (opcode[3]) begin // LDx A, (HL)
- rd <= 1;
- end else begin
- wr <= 1;
- wdata <= registers[`REG_A];
- end
- end
- 1: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- end
- endcase
- end
- `INSN_ALU8: begin
- if ((opcode[2:0] == `INSN_reg_dHL) && (cycle == 0)) begin
- // fffffffff fuck your shit, read from (HL) :(
- rd <= 1;
- address <= {registers[`REG_H], registers[`REG_L]};
- end else begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- case (opcode[2:0])
- `INSN_reg_A: tmp <= registers[`REG_A];
- `INSN_reg_B: tmp <= registers[`REG_B];
- `INSN_reg_C: tmp <= registers[`REG_C];
- `INSN_reg_D: tmp <= registers[`REG_D];
- `INSN_reg_E: tmp <= registers[`REG_E];
- `INSN_reg_H: tmp <= registers[`REG_H];
- `INSN_reg_L: tmp <= registers[`REG_L];
- `INSN_reg_dHL: tmp <= rdata;
- endcase
- end
- end
- `INSN_NOP: begin
- `EXEC_NEWCYCLE;
- `EXEC_INC_PC;
- end
- `INSN_RST: begin
- case (cycle)
- 0: begin
- `EXEC_INC_PC; // This goes FIRST in RST
- end
- 1: begin
- wr <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
- wdata <= registers[`REG_PCH];
- end
- 2: begin
- wr <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]}-2;
- wdata <= registers[`REG_PCL];
- end
- 3: begin
- `EXEC_NEWCYCLE;
- {registers[`REG_PCH],registers[`REG_PCL]} <=
- {10'b0,opcode[5:3],3'b0};
- end
- endcase
- end
- `INSN_RET: begin
- case (cycle)
- 0: begin
- rd <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]};
- end
- 1: begin
- rd <= 1;
- address <= {registers[`REG_SPH],registers[`REG_SPL]} + 1;
- end
- 2: begin /* twiddle thumbs */ end
- 3: begin
- `EXEC_NEWCYCLE;
- // do NOT increment PC!
- end
- endcase
- end
- `INSN_CALL: begin
- case (cycle)
- 0: begin
- `EXEC_INC_PC;
- `EXEC_NEXTADDR_PCINC;
- rd <= 1;
- end
- 1: begin
- `EXEC_INC_PC;
- `EXEC_NEXTADDR_PCINC;
- rd <= 1;
- end
- 2: begin
- `EXEC_INC_PC;
- end
- 3: begin
- address <= {registers[`REG_SPH],registers[`REG_SPL]} - 1;
- wdata <= registers[`REG_PCH];
- wr <= 1;
- end
- 4: begin
- address <= {registers[`REG_SPH],registers[`REG_SPL]} - 2;
- wdata <= registers[`REG_PCL];
- wr <= 1;
- end
- 5: begin
- `EXEC_NEWCYCLE; /* do NOT increment the PC */
- end
- endcase
- end
+ `define EXECUTE
+ `include "allinsns.v"
+ `undef EXECUTE
default:
$stop;
endcase
end
`STATE_WRITEBACK: begin
casex (opcode)
- `INSN_LD_reg_imm8:
- case (cycle)
- 0: begin end
- 1: case (opcode[5:3])
- `INSN_reg_A: begin registers[`REG_A] <= rdata; end
- `INSN_reg_B: begin registers[`REG_B] <= rdata; end
- `INSN_reg_C: begin registers[`REG_C] <= rdata; end
- `INSN_reg_D: begin registers[`REG_D] <= rdata; end
- `INSN_reg_E: begin registers[`REG_E] <= rdata; end
- `INSN_reg_H: begin registers[`REG_H] <= rdata; end
- `INSN_reg_L: begin registers[`REG_L] <= rdata; end
- `INSN_reg_dHL: begin /* Go off to cycle 2 */ end
- endcase
- 2: begin end
- endcase
- `INSN_HALT: begin
- /* Nothing needs happen here. */
- /* XXX Interrupts needed for HALT. */
- end
- `INSN_LD_HL_reg: begin
- /* Nothing of interest here */
- end
- `INSN_LD_reg_HL: begin
- case (cycle)
- 0: begin end
- 1: begin
- case (opcode[5:3])
- `INSN_reg_A: registers[`REG_A] <= tmp;
- `INSN_reg_B: registers[`REG_B] <= tmp;
- `INSN_reg_C: registers[`REG_C] <= tmp;
- `INSN_reg_D: registers[`REG_D] <= tmp;
- `INSN_reg_E: registers[`REG_E] <= tmp;
- `INSN_reg_H: registers[`REG_H] <= tmp;
- `INSN_reg_L: registers[`REG_L] <= tmp;
- endcase
- end
- endcase
- end
- `INSN_LD_reg_reg: begin
- case (opcode[5:3])
- `INSN_reg_A: registers[`REG_A] <= tmp;
- `INSN_reg_B: registers[`REG_B] <= tmp;
- `INSN_reg_C: registers[`REG_C] <= tmp;
- `INSN_reg_D: registers[`REG_D] <= tmp;
- `INSN_reg_E: registers[`REG_E] <= tmp;
- `INSN_reg_H: registers[`REG_H] <= tmp;
- `INSN_reg_L: registers[`REG_L] <= tmp;
- endcase
- end
- `INSN_LD_reg_imm16: begin
- case (cycle)
- 0: begin /* */ end
- 1: begin
- case (opcode[5:4])
- `INSN_reg16_BC: registers[`REG_C] <= rdata;
- `INSN_reg16_DE: registers[`REG_E] <= rdata;
- `INSN_reg16_HL: registers[`REG_L] <= rdata;
- `INSN_reg16_SP: registers[`REG_SPL] <= rdata;
- endcase
- end
- 2: begin
- case (opcode[5:4])
- `INSN_reg16_BC: registers[`REG_B] <= rdata;
- `INSN_reg16_DE: registers[`REG_D] <= rdata;
- `INSN_reg16_HL: registers[`REG_H] <= rdata;
- `INSN_reg16_SP: registers[`REG_SPH] <= rdata;
- endcase
- end
- endcase
- end
- `INSN_LD_SP_HL: begin
- case (cycle)
- 0: registers[`REG_SPH] <= tmp;
- 1: registers[`REG_SPL] <= tmp;
- endcase
- end
- `INSN_PUSH_reg: begin /* PUSH is 16 cycles! */
- case (cycle)
- 0: {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} - 1;
- 1: {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} - 1;
- 2: begin /* type F */ end
- 3: begin /* type F */ end
- endcase
- end
- `INSN_POP_reg: begin /* POP is 12 cycles! */
- case (cycle)
- 0: {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} + 1;
- 1: begin
- case (opcode[5:4])
- `INSN_stack_AF: registers[`REG_F] <= rdata;
- `INSN_stack_BC: registers[`REG_C] <= rdata;
- `INSN_stack_DE: registers[`REG_E] <= rdata;
- `INSN_stack_HL: registers[`REG_L] <= rdata;
- endcase
- {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} + 1;
- end
- 2: begin
- case (opcode[5:4])
- `INSN_stack_AF: registers[`REG_A] <= rdata;
- `INSN_stack_BC: registers[`REG_B] <= rdata;
- `INSN_stack_DE: registers[`REG_D] <= rdata;
- `INSN_stack_HL: registers[`REG_H] <= rdata;
- endcase
- end
- endcase
- end
- `INSN_LDH_AC: begin
- case (cycle)
- 0: begin /* Type F */ end
- 1: if (opcode[4])
- registers[`REG_A] <= rdata;
- endcase
- end
- `INSN_LDx_AHL: begin
- case (cycle)
- 0: begin /* Type F */ end
- 1: begin
- if (opcode[3])
- registers[`REG_A] <= rdata;
- {registers[`REG_H],registers[`REG_L]} <=
- opcode[4] ? // if set, LDD, else LDI
- ({registers[`REG_H],registers[`REG_L]} - 1) :
- ({registers[`REG_H],registers[`REG_L]} + 1);
- end
- endcase
- end
- `INSN_ALU8: begin
- if ((opcode[2:0] == `INSN_reg_dHL) && (cycle == 0)) begin
- /* Sit on our asses. */
- end else begin /* Actually do the computation! */
- case (opcode[5:3])
- `INSN_alu_ADD: begin
- registers[`REG_A] <=
- registers[`REG_A] + tmp;
- registers[`REG_F] <=
- { /* Z */ ((registers[`REG_A] + tmp) == 0) ? 1'b1 : 1'b0,
- /* N */ 1'b0,
- /* H */ (({1'b0,registers[`REG_A][3:0]} + {1'b0,tmp[3:0]}) >> 4 == 1) ? 1'b1 : 1'b0,
- /* C */ (({1'b0,registers[`REG_A]} + {1'b0,tmp}) >> 8 == 1) ? 1'b1 : 1'b0,
- registers[`REG_F][3:0]
- };
- end
- `INSN_alu_ADC: begin
- registers[`REG_A] <=
- registers[`REG_A] + tmp + {7'b0,registers[`REG_F][4]};
- registers[`REG_F] <=
- { /* Z */ ((registers[`REG_A] + tmp + {7'b0,registers[`REG_F][4]}) == 0) ? 1'b1 : 1'b0,
- /* N */ 1'b0,
- /* H */ (({1'b0,registers[`REG_A][3:0]} + {1'b0,tmp[3:0]} + {4'b0,registers[`REG_F][4]}) >> 4 == 1) ? 1'b1 : 1'b0,
- /* C */ (({1'b0,registers[`REG_A]} + {1'b0,tmp} + {8'b0,registers[`REG_F][4]}) >> 8 == 1) ? 1'b1 : 1'b0,
- registers[`REG_F][3:0]
- };
- end
- `INSN_alu_AND: begin
- registers[`REG_A] <=
- registers[`REG_A] & tmp;
- registers[`REG_F] <=
- { /* Z */ ((registers[`REG_A] & tmp) == 0) ? 1'b1 : 1'b0,
- 3'b010,
- registers[`REG_F][3:0]
- };
- end
- `INSN_alu_OR: begin
- registers[`REG_A] <=
- registers[`REG_A] | tmp;
- registers[`REG_F] <=
- { /* Z */ ((registers[`REG_A] | tmp) == 0) ? 1'b1 : 1'b0,
- 3'b000,
- registers[`REG_F][3:0]
- };
- end
- `INSN_alu_XOR: begin
- registers[`REG_A] <=
- registers[`REG_A] ^ tmp;
- registers[`REG_F] <=
- { /* Z */ ((registers[`REG_A] ^ tmp) == 0) ? 1'b1 : 1'b0,
- 3'b000,
- registers[`REG_F][3:0]
- };
- end
- default:
- $stop;
- endcase
- end
- end
- `INSN_NOP: begin /* NOP! */ end
- `INSN_RST: begin
- case (cycle)
- 0: begin /* type F */ end
- 1: begin /* type F */ end
- 2: begin /* type F */ end
- 3: {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]}-2;
- endcase
- end
- `INSN_RET: begin
- case (cycle)
- 0: begin /* type F */ end
- 1: registers[`REG_PCL] <= rdata;
- 2: registers[`REG_PCH] <= rdata;
- 3: begin
- {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} + 2;
- if (opcode[4]) /* RETI */
- ie <= 1;
- end
- endcase
- end
- `INSN_CALL: begin
- case (cycle)
- 0: begin /* type F */ end
- 1: tmp <= rdata; // tmp contains newpcl
- 2: tmp2 <= rdata; // tmp2 contains newpch
- 3: begin /* type F */ end
- 4: registers[`REG_PCH] <= tmp2;
- 5: begin
- {registers[`REG_SPH],registers[`REG_SPL]} <=
- {registers[`REG_SPH],registers[`REG_SPL]} - 2;
- registers[`REG_PCL] <= tmp;
- end
- endcase
- end
+ `define WRITEBACK
+ `include "allinsns.v"
+ `undef WRITEBACK
default:
$stop;
endcase
end
endcase
endmodule
-
-`timescale 1ns / 1ps
-module ROM(
- input [15:0] address,
- inout [7:0] data,
- input clk,
- input wr, rd);
-
- reg [7:0] rom [2047:0];
- initial $readmemh("rom.hex", rom);
-
- wire decode = address[15:13] == 0;
- wire [7:0] odata = rom[address[11:0]];
- assign data = (rd && decode) ? odata : 8'bzzzzzzzz;
- //assign data = rd ? odata : 8'bzzzzzzzz;
-endmodule
-
-module InternalRAM(
- input [15:0] address,
- inout [7:0] data,
- input clk,
- input wr, rd);
-
- reg [7:0] ram [8191:0];
-
- wire decode = (address >= 16'hC000) && (address < 16'hFE00);
- reg [7:0] odata;
- wire idata = data;
- assign data = (rd && decode) ? odata : 8'bzzzzzzzz;
-
- always @(negedge clk)
- begin
- if (decode && rd)
- odata <= ram[address[12:0]];
- else if (decode && wr)
- ram[address[12:0]] <= data;
- end
-endmodule
-
-module Switches(
- input [15:0] address,
- inout [7:0] data,
- input clk,
- input wr, rd,
- input [7:0] switches,
- output reg [7:0] ledout);
-
- wire decode = address == 16'hFF51;
- reg [7:0] odata;
- wire idata = data;
- assign data = (rd && decode) ? odata : 8'bzzzzzzzz;
-
- always @(negedge clk)
- begin
- if (decode && rd)
- odata <= switches;
- else if (decode && wr)
- ledout <= data;
- end
-endmodule
-
-module CoreTop(
- input xtal,
- input [1:0] switches,
- output wire [7:0] leds,
- output serio,
- output wire [3:0] digits,
- output wire [7:0] seven);
-
- wire clk;
- //IBUFG ibuf (.O(clk), .I(iclk));
-
- CPUDCM dcm (.CLKIN_IN(xtal), .CLKFX_OUT(clk));
-
- wire [15:0] addr;
- wire [7:0] data;
- wire wr, rd;
-
- wire [7:0] ledout;
- assign leds = switches[1] ? (switches[0]?{rd,wr,addr[5:0]}:data[7:0])
- : ledout;
-
- GBZ80Core core(
- .clk(clk),
- .busaddress(addr),
- .busdata(data),
- .buswr(wr),
- .busrd(rd));
-
- ROM rom(
- .address(addr),
- .data(data),
- .clk(clk),
- .wr(wr),
- .rd(rd));
-
- AddrMon amon(
- .addr(addr),
- .clk(clk),
- .digit(digits),
- .out(seven)
- );
-
- Switches sw(
- .address(addr),
- .data(data),
- .clk(clk),
- .wr(wr),
- .rd(rd),
- .ledout(ledout),
- .switches(0)
- );
-
- UART nouart (
- .clk(clk),
- .wr(wr),
- .rd(rd),
- .addr(addr),
- .data(data),
- .serial(serio)
- );
-endmodule
-
-module TestBench();
- reg clk = 0;
- wire [15:0] addr;
- wire [7:0] data;
- wire wr, rd;
-
-// wire [7:0] leds;
-// wire [7:0] switches;
-
- always #10 clk <= ~clk;
- GBZ80Core core(
- .clk(clk),
- .busaddress(addr),
- .busdata(data),
- .buswr(wr),
- .busrd(rd));
-
- ROM rom(
- .clk(clk),
- .address(addr),
- .data(data),
- .wr(wr),
- .rd(rd));
-
-// InternalRAM ram(
-// .address(addr),
-// .data(data),
-// .clk(clk),
-// .wr(wr),
-// .rd(rd));
-
-// wire serio;
-// UART uart(
-// .addr(addr),
-// .data(data),
-// .clk(clk),
-// .wr(wr),
-// .rd(rd),
-// .serial(serio));
-
-// Switches sw(
-// .clk(clk),
-// .address(addr),
-// .data(data),
-// .wr(wr),
-// .rd(rd),
-// .switches(switches),
-// .leds(leds));
-endmodule