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//////////////////////////////////////////////////////////////////////////////// // Company: // // Engineer: Scott Moore // // // // Create Date: 11:45:32 09/04/2006 // // Design Name: // // Module Name: cpu8080 // // Project Name: cpu8080 // // Target Devices: xc3c200, xc3s1000 // // Tool versions: // // Description: // // // // Executes the 8080 instruction set. It is designed to be an internal // // cell. Each of the I/Os are positive logic, and all signals are // // constant with the exception of the data bus. The control signals are // // fully decoded (unlike the orignal 8080), and features read and write // // signals for both memory and I/O space. The I/O space is an 8 bit // // address as in the original 8080. It does NOT echo the lower 8 bits to // // the higher 8 bits, as was the practice in some systems. // // // // Like the original 8080, the interrupt vectoring is fully external. The // // the external controller forces a full instruction onto the data bus. // // The sequence begins with the assertion of interrupt request. The CPU // // will then assert interrupt acknowledge, then it will run a special // // read cycle with inta asserted for each cycle of a possibly // // multibyte instruction. This matches the original 8080, which typically // // used single byte restart instructions to form a simple interrupt // // controller, but was capable of full vectoring via insertion of a jump, // // call or similar instruction. // // // // Note that the interrupt vector instruction should branch. This is // // because the PC gets changed by the vector instruction, so if it does // // not branch, it will have skipped a number of bytes after the interrupt // // equivalent to the vector instruction. The only instructions that // // should really be used to vector are jmp, rst and call instructions. // // Specifically, rst and call instruction compensate for the pc movement // // by putting the pc unmodified on the stack. // // // // The memory, I/O and interrupt fetches all obey a simple clocking // // sequence as follows. The CPU uses the positive clock edge to assert // // and sample signals and data. The external logic theoretically uses the // // negative edge to check signal assertions and sample data, but it can // // either use the negative edge, or actually be asynronous logic. // // // // A standard read sequence is as follows: // // // // 1. At the positive clock edge, readmem, readio or readint is asserted. // // 2. At the negative clock edge (or immediately), the external memory // // places data onto the data bus. // // 3. We hold automatically for one cycle. // // 4. At the next positive clock edge, the data is sampled, and the read // // Signal is deasserted. // // // // A standard write sequence is as follows: // // // // 1. At the positive edge, data is asserted on the data bus. // // 2. At the next postive clock edge, writemem or writeio is asserted. // // 3. At the next positive clock edge, writemem or writeio is deasserted. // // 4. At the next positive edge, the data is deasserted. // // // // Dependencies: // // // // Revision: // // Revision 0.01 - File Created // // Additional Comments: // // // //////////////////////////////////////////////////////////////////////////////// `timescale 1ns / 1ps // // CPU states // `define cpus_idle 6'h00 // Idle `define cpus_fetchi 6'h01 // Instruction fetch `define cpus_fetchi2 6'h02 // Instruction fetch 2 `define cpus_fetchi3 6'h03 // Instruction fetch 3 `define cpus_fetchi4 6'h04 // Instruction fetch 4 `define cpus_halt 6'h05 // Halt (wait for interrupt) `define cpus_alucb 6'h06 // alu cycleback `define cpus_indcb 6'h07 // inr/dcr cycleback `define cpus_movmtbc 6'h08 // Move memory to bc `define cpus_movmtde 6'h09 // Move memory to de `define cpus_movmthl 6'h0a // Move memory to hl `define cpus_movmtsp 6'h0b // Move memory to sp `define cpus_lhld 6'h0c // LHLD `define cpus_jmp 6'h0d // JMP `define cpus_write 6'h0e // write byte `define cpus_write2 6'h0f // write byte #2 `define cpus_write3 6'h10 // write byte #3 `define cpus_write4 6'h11 // write byte #4 `define cpus_read 6'h12 // read byte `define cpus_read2 6'h13 // read byte #2 `define cpus_read3 6'h14 // read byte #3 `define cpus_pop 6'h15 // POP completion `define cpus_in 6'h16 // IN `define cpus_in2 6'h17 // IN #2 `define cpus_in3 6'h18 // IN #3 `define cpus_out 6'h19 // OUT `define cpus_out2 6'h1a // OUT #2 `define cpus_out3 6'h1b // OUT #3 `define cpus_out4 6'h1c // OUT #4 `define cpus_movtr 6'h1d // move to register `define cpus_movrtw 6'h1e // move read to write `define cpus_movrtwa 6'h1f // move read to write address `define cpus_movrtra 6'h20 // move read to read address `define cpus_accimm 6'h21 // accumulator immediate operations `define cpus_daa 6'h22 // DAA completion // // Register numbers // `define reg_b 3'b000 // B `define reg_c 3'b001 // C `define reg_d 3'b010 // D `define reg_e 3'b011 // E `define reg_h 3'b100 // H `define reg_l 3'b101 // L `define reg_m 3'b110 // M `define reg_a 3'b111 // A // // ALU operations // `define aluop_add 3'b000 // add `define aluop_adc 3'b001 // add with carry in `define aluop_sub 3'b010 // subtract `define aluop_sbb 3'b011 // subtract with borrow in `define aluop_and 3'b100 // and `define aluop_xor 3'b101 // xor `define aluop_or 3'b110 // or `define aluop_cmp 3'b111 // compare // // State macros // `define mac_writebyte 1 // write a byte `define mac_readbtoreg 2 // read a byte, place in register `define mac_readdtobc 4 // read double byte to BC `define mac_readdtode 6 // read double byte to DE `define mac_readdtohl 8 // read double byte to HL `define mac_readdtosp 10 // read double byte to SP `define mac_readbmtw 12 // read byte and move to write `define mac_readbmtr 14 // read byte and move to register `define mac_sta 16 // STA `define mac_lda 20 // LDA `define mac_shld 25 // SHLD `define mac_lhld 30 // LHLD `define mac_writedbyte 36 // write double byte `define mac_pop 38 // POP `define mac_xthl 40 // XTHL `define mac_accimm 44 // accumulator immediate `define mac_jmp 45 // JMP `define mac_call 47 // CALL `define mac_in 51 // IN `define mac_out 52 // OUT `define mac_rst 53 // RST module SM8080 (addr, // Address out data, // Data bus readmem, // Memory read writemem, // Memory write readio, // Read I/O space writeio, // Write I/O space intr, // Interrupt request inta, // Interrupt request waitr, // Wait request reset, // Reset clock); // System clock output [15:0] addr; inout [7:0] data; output readmem; output writemem; output readio; output writeio; input intr; output inta; input waitr; input reset; input clock; // synthesis clock // Output or input lines that need to be registered reg readmem; reg writemem; reg [15:0] pc; reg [15:0] addr; reg readio; reg writeio; reg inta; reg [15:0] sp; // Local registers reg [5:0] state; // CPU state machine reg [2:0] regd; // Destination register reg [7:0] datao; // Data output register reg dataeno; // Enable output data reg [15:0] waddrhold; // address holding for write reg [15:0] raddrhold; // address holding for read reg [7:0] wdatahold; // single byte write data holding reg [7:0] wdatahold2; // single byte write data holding reg [7:0] rdatahold; // single byte read data holding reg [7:0] rdatahold2; // single byte read data holding reg [1:0] popdes; // POP destination code reg [5:0] statesel; // state map selector reg [5:0] nextstate; // next state output reg eienb; // interrupt enable delay shift reg reg [7:0] opcode; // opcode holding // Register file. Note that 3'b110 (6) is not used, and is the code for a // memory reference. reg [7:0] regfil[0:7]; // The flags are represented individually reg carry; // carry bit reg auxcar; // auxiliary carry bit reg sign; // sign bit reg zero; // zero bit reg parity; // parity bit reg ei; // interrupt enable reg intcyc; // in interrupt cycle // ALU communication wire [7:0] alures; // result reg [7:0] aluopra; // left side operand reg [7:0] aluoprb; // right side operand reg alucin; // carry in wire alucout; // carry out wire alupar; // parity out wire aluaxc; // auxiliary carry reg [2:0] alusel; // alu operational select wire aluzout; // CNS wire alusout; // CNS // Instantiate the ALU alu alu(alures, aluopra, aluoprb, alucin, alucout, aluzout, alusout, alupar, aluaxc, alusel); always @(posedge clock) if (reset) begin // syncronous reset actions state <= `cpus_fetchi; // Clear CPU state to initial fetch pc <= 0; // reset program counter to 1st location dataeno <= 0; // get off the data bus readmem <= 0; // all signals out false writemem<= 0; readio <= 0; writeio <= 0; inta <= 0; intcyc <= 0; ei <= 1; eienb <= 0; end else case (state) `cpus_fetchi: begin // start of instruction fetch // if interrupt request is on, enter interrupt cycle, else exit it now if (intr&&ei) begin intcyc <= 1;// enter interrupt cycle inta <= 1; // activate interrupt acknowledge ei <= 0; // disable interrupts end else begin intcyc <= 0; // leave interrupt cycle readmem <= 1; // activate instruction memory read end addr <= pc; // place current program count on output if (eienb) ei <=1; // process delayed interrupt enable eienb <=0; // reset interrupt enabler state <= `cpus_fetchi2; // next state end `cpus_fetchi2: begin // wait state <= `cpus_fetchi3; // next state end `cpus_fetchi3: begin // complete instruction memory read if (!waitr) begin // no wait selected, otherwise cycle opcode <= data; // latch opcode readmem <= 0; // Deactivate instruction memory read inta <= 0; // and interrupt acknowledge state <= `cpus_fetchi4; // next state end end `cpus_fetchi4: begin // complete instruction memory read // We split off the instructions into 4 groups. Most of the 8080 // instructions are in the MOV and ACC operations class. case (opcode[7:6]) // Decode top level 2'b00: begin // 00: Data transfers and others case (opcode[5:0]) // decode these instructions 6'b000000: begin // NOP // yes, do nothing state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte CNS end 6'b110111: begin // STC carry <= 1; // set carry flag state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte CNS end 6'b111111: begin // CMC carry <= ~carry; // complement carry flag state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte CNS end 6'b101111: begin // CMA regfil[`reg_a] <= ~regfil[`reg_a]; // complement accumulator state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte CNS end 6'b100111: begin // DAA // decimal adjust accumulator, or remove by carry any // results in nybbles greater than 9 if (regfil[`reg_a][3:0] > 9 || auxcar) begin { carry, regfil[`reg_a] } <= regfil[`reg_a]+ 3'b110; // CNS 6 auxcar <= ((regfil[`reg_a][3:0]+6 >> 4) & 1'b1) ? 1'b1:1'b0; // cns end state <= `cpus_daa; // finish DAA pc <= pc+1'b1; // Next instruction byte end 6'b000100, 6'b001100, 6'b010100, 6'b011100, 6'b100100, 6'b101100, 6'b110100, 6'b111100, 6'b000101, 6'b001101, 6'b010101, 6'b011101, 6'b100101, 6'b101101, 6'b110101, 6'b111101: begin // INR/DCR regd <= opcode[5:3]; // get source/destination reg aluopra <= regfil[opcode[5:3]]; // load as alu a aluoprb <= 1; // load 1 as alu b if (opcode[0]) alusel <= `aluop_sub; // set subtract else alusel <= `aluop_add; // set add state <= `cpus_indcb; // go inr/dcr cycleback pc <= pc+1'b1; // Next instruction byte end 6'b000010, 6'b010010: begin // STAX wdatahold <= regfil[`reg_a]; // place A as source if (opcode[4]) // use DE pair waddrhold <= regfil[`reg_d]<<8|regfil[`reg_d]; else // use BC pair waddrhold <= regfil[`reg_b] << 8|regfil[`reg_c]; statesel <= `mac_writebyte; // write byte state <= `cpus_write; pc <= pc+1'b1; // Next instruction byte end 6'b001010, 6'b011010: begin // LDAX regd <= `reg_a; // set A as destination if (opcode[4]) // use DE pair raddrhold <= regfil[`reg_d]<<8|regfil[`reg_d]; else // use BC pair raddrhold <= regfil[`reg_b]<<8|regfil[`reg_c]; statesel <= `mac_readbtoreg; // read byte to register state <= `cpus_read; pc <= pc+1'b1; // Next instruction byte end 6'b000111: begin // RLC // rotate left circular { carry, regfil[`reg_a] } <= (regfil[`reg_a] << 1)+regfil[`reg_a][7]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b010111: begin // RAL // rotate left through carry { carry, regfil[`reg_a] } <= (regfil[`reg_a] << 1)+carry; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b001111: begin // RRC // rotate right circular regfil[`reg_a] <= (regfil[`reg_a] >> 1)+(regfil[`reg_a][0] << 7); carry <= regfil[`reg_a][0]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b011111: begin // RAR // rotate right through carry regfil[`reg_a] <= (regfil[`reg_a] >> 1)+(carry << 7); carry <= regfil[`reg_a][0]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b001001: begin // DAD B // add BC to HL { carry, regfil[`reg_h], regfil[`reg_l] } <= (regfil[`reg_h] << 8)+regfil[`reg_l]+ (regfil[`reg_b] << 8)+regfil[`reg_c]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b011001: begin // DAD D // add DE to HL { carry, regfil[`reg_h], regfil[`reg_l] } <= (regfil[`reg_h] << 8)+regfil[`reg_l]+ (regfil[`reg_d] << 8)+regfil[`reg_e]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b101001: begin // DAD H // add HL to HL { carry, regfil[`reg_h], regfil[`reg_l] } <= (regfil[`reg_h] << 8)+regfil[`reg_l]+ (regfil[`reg_h] << 8)+regfil[`reg_l]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b111001: begin // DAD SP // add SP to HL { carry, regfil[`reg_h], regfil[`reg_l] } <= (regfil[`reg_h] << 8)+regfil[`reg_l]+sp; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b000011: begin // INX B // increment BC, no flags set regfil[`reg_b] <= (((regfil[`reg_b] << 8)+regfil[`reg_c])+1'b1)>>8; regfil[`reg_c] <= ((regfil[`reg_b] << 8)+regfil[`reg_c])+1'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b010011: begin // INX D // increment DE, no flags set regfil[`reg_d] <= (((regfil[`reg_d] << 8)+regfil[`reg_e])+1'b1)>>8; regfil[`reg_e] <= ((regfil[`reg_d] << 8)+regfil[`reg_e])+1'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b100011: begin // INX H // increment HL, no flags set regfil[`reg_h] <= (((regfil[`reg_h] << 8)+regfil[`reg_l])+1'b1)>>8; regfil[`reg_l] <= ((regfil[`reg_h] << 8)+regfil[`reg_l])+1'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b110011: begin // INX SP // increment SP, no flags set sp <= sp + 16'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b001011: begin // DCX B // decrement BC, no flags set regfil[`reg_b] <= (((regfil[`reg_b] << 8)+regfil[`reg_c]) - 8'b1)>>8; regfil[`reg_c] <= ((regfil[`reg_b] << 8)+regfil[`reg_c])- 8'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc + 1'b1; // Next instruction byte end 6'b011011: begin // DCX D // decrement DE, no flags set regfil[`reg_d] <= (((regfil[`reg_d] << 8)+regfil[`reg_e]) - 8'b1)>>8; regfil[`reg_e] <= ((regfil[`reg_d] << 8)+regfil[`reg_e])- 8'd11; // cns 11 state <= `cpus_fetchi; // Fetch next instruction pc <= pc + 1'b1; // Next instruction byte end 6'b101011: begin // DCX H // decrement HL, no flags set regfil[`reg_h] <= (((regfil[`reg_h] << 8)+regfil[`reg_l])- 8'b1)>>8; regfil[`reg_l] <= ((regfil[`reg_h] << 8)+regfil[`reg_l]) - 8'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b111011: begin // DCX SP // decrement SP, no flags set sp <= sp - 16'b1; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b000001: begin // LXI B raddrhold <= pc+1'b1; // pick up after instruction statesel <= `mac_readdtobc; // read double to BC state <= `cpus_read; pc <= pc + 16'h3; // skip end 6'b010001: begin // LXI D raddrhold <= pc+1'b1; // pick up after instruction statesel <= `mac_readdtode; // read double to DE state <= `cpus_read; pc <= pc + 16'h3; // skip end 6'b100001: begin // LXI H raddrhold <= pc+1'b1; // pick up after instruction statesel <= `mac_readdtohl; // read double to HL state <= `cpus_read; pc <= pc + 16'h3; // skip end 6'b110001: begin // LXI SP raddrhold <= pc+1'b1; // pick up after instruction pc <= pc + 16'h3; // skip statesel <= `mac_readdtosp; // read double to SP state <= `cpus_read; pc <= pc + 16'h3; // skip end 6'b000110, 6'b001110, 6'b010110, 6'b011110, 6'b100110, 6'b101110, 6'b110110, 6'b111110: begin // MVI // move immediate to register regd <= opcode[5:3]; // set destination register raddrhold <= pc+1'b1; // set pickup address if (opcode[5:3] == `reg_m) begin // it's mvi m,imm regd <= opcode[5:3]; // set destination register // set destination address waddrhold <= { regfil[`reg_h], regfil[`reg_l] }; statesel <= `mac_readbmtw; // read byte and move to write end else statesel <= `mac_readbmtr; // read byte and move to register state <= `cpus_read; pc <= pc + 16'h2; // advance over byte end 6'b110010: begin // STA wdatahold <= regfil[`reg_a]; // set write data raddrhold <= pc+1'b1; // set read address statesel <= `mac_sta; // perform sta state <= `cpus_read; pc <= pc + 16'h3; // next end 6'b111010: begin // LDA raddrhold <= pc+1'b1; // set read address regd <= `reg_a; // set destination statesel <= `mac_lda; // perform lda state <= `cpus_read; pc <= pc + 16'h3; // next end 6'b100010: begin // SHLD wdatahold <= regfil[`reg_l]; // set write data wdatahold2 <= regfil[`reg_h]; raddrhold <= pc+1'b1; // set read address statesel <= `mac_shld; // perform SHLD state <= `cpus_read; pc <= pc + 16'h3; // next end 6'b101010: begin // LHLD raddrhold <= pc+1'b1; // set read address statesel <= `mac_lhld; // perform LHLD state <= `cpus_read; pc <= pc + 16'h3; // next end // the illegal opcodes behave as NOPs 6'b001000, 6'b010000, 6'b011000, 6'b100000, 6'b101000, 6'b110000, 6'b110000: begin state <= `cpus_fetchi; // fetch next instruction pc <= pc+1'b1; // Next instruction byte end endcase end 2'b01: begin // 01: MOV instruction // Check its the halt instruction, which occupies the invalid // "MOV M,M" instruction. if (opcode == 8'b01110110) state <= `cpus_halt; // Otherwise, the 01 prefix is single instruction format. else begin // Format 01DDDSSS // Check memory source, use state if so if (opcode[2:0] == `reg_m) begin // place hl as address raddrhold <= regfil[`reg_h]<<8|regfil[`reg_l]; regd <= opcode[5:3]; // set destination statesel <= `mac_readbtoreg; // read byte to register state <= `cpus_read; // Check memory destination, use state if so end else if (regd == `reg_m) begin // place hl as address waddrhold <= regfil[`reg_h]<<8|regfil[`reg_l]; wdatahold <= regfil[opcode[2:0]]; // place data to write statesel <= `mac_writebyte; // write byte state <= `cpus_write; // otherwise simple register to register end else begin regfil[opcode[5:3]] <= regfil[opcode[2:0]]; state <= `cpus_fetchi; // Fetch next instruction end end pc <= pc+1'b1; // Next instruction byte end 2'b10: begin // 10: Reg or mem to accumulator ops // 10 prefix is single instruction format aluopra <= regfil[`reg_a]; // load as alu a aluoprb <= regfil[opcode[2:0]]; // load as alu b alusel <= opcode[5:3]; // set alu operation from instruction alucin <= carry; // input carry if (opcode[2:0] == `reg_m) begin // set read address raddrhold <= regfil[`reg_h]<<8|regfil[`reg_l]; regd <= `reg_a; // set destination always a statesel <= `mac_readbtoreg; // read byte to register state <= `cpus_read; end else state <= `cpus_alucb; // go to alu cycleback pc <= pc+1'b1; // Next instruction byte end 2'b11: begin // 11: jmp/call and others case (opcode[5:0]) // decode these instructions 6'b000101, 6'b010101, 6'b100101, 6'b110101: begin // PUSH waddrhold <= sp - 16'h2; // write to stack sp <= sp - 16'h2; // pushdown stack case (opcode[5:4]) // register set 2'b00: { wdatahold2, wdatahold } <= { regfil[`reg_b], regfil[`reg_c] }; 2'b01: { wdatahold2, wdatahold } <= { regfil[`reg_d], regfil[`reg_e] }; 2'b10: { wdatahold2, wdatahold } <= { regfil[`reg_h], regfil[`reg_l] }; 2'b11: { wdatahold2, wdatahold } <= { regfil[`reg_a], sign, zero, 1'b0, auxcar, 1'b0, parity, 1'b1, carry }; endcase statesel <= `mac_writedbyte; // write double byte state <= `cpus_write; pc <= pc+1'b1; // Next instruction byte end 6'b000001, 6'b010001, 6'b100001, 6'b110001: begin // POP popdes <= opcode[5:4]; // set destination raddrhold <= sp; // read from stack sp <= sp + 16'h2; // pushup stack statesel <= `mac_pop; // perform POP state <= `cpus_read; pc <= pc+1'b1; // Next instruction byte end 6'b101011: begin // XCHG regfil[`reg_d] <= regfil[`reg_h]; regfil[`reg_e] <= regfil[`reg_l]; regfil[`reg_h] <= regfil[`reg_d]; regfil[`reg_l] <= regfil[`reg_e]; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b100011: begin // XTHL raddrhold <= sp; // address SP for read waddrhold <= sp; // address SP for write wdatahold <= regfil[`reg_l]; // set data is HL wdatahold2 <= regfil[`reg_h]; statesel <= `mac_xthl; // perform XTHL state <= `cpus_read; pc <= pc+1'b1; // Next instruction byte end 6'b111001: begin // SPHL sp <= { regfil[`reg_h], regfil[`reg_l] }; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b000110, 6'b001110, 6'b010110, 6'b011110, 6'b100110, 6'b101110, 6'b110110, 6'b111110: begin // immediate arithmetic to accumulator aluopra <= regfil[`reg_a]; // load as alu a alusel <= opcode[5:3]; // set alu operation from instruction alucin <= carry; // input carry raddrhold <= pc + 1'b1; // read at PC statesel <= `mac_accimm; // finish accumulator immediate state <= `cpus_read; pc <= pc + 16'h2; // skip immediate byte end 6'b101001: begin // PCHL state <= `cpus_fetchi; // Fetch next instruction pc <= { regfil[`reg_h], regfil[`reg_l] }; end 6'b000011: begin // JMP raddrhold <= pc+1'b1; // pick up jump address statesel <= `mac_jmp; // finish JMP state <= `cpus_read; end 6'b000010, 6'b001010, 6'b010010, 6'b011010, 6'b100010, 6'b101010, 6'b110010, 6'b111010: begin // Jcc raddrhold <= pc+1'b1; // pick up jump address statesel <= `mac_jmp; // finish JMP // choose continue or read according to condition case (opcode[5:3]) // decode flag cases 3'b000: if (zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b001: if (!zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b010: if (carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b011: if (!carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b100: if (parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b101: if (!parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b110: if (sign) state <= `cpus_fetchi; else state <= `cpus_read; 3'b111: if (!sign) state <= `cpus_fetchi; else state <= `cpus_read; endcase pc <= pc + 16'h3; // advance after jump for false end 6'b001101: begin // CALL raddrhold <= pc+1'b1; // pick up call address waddrhold <= sp - 16'h2; // place address on stack // if interrupt cycle, use current pc, else use address // after call if (intcyc) { wdatahold2, wdatahold } <= pc; else { wdatahold2, wdatahold } <= pc + 16'h3; sp <= sp - 16'h2; // pushdown stack statesel <= `mac_call; // finish CALL state <= `cpus_read; end 6'b000100, 6'b001100, 6'b010100, 6'b011100, 6'b100100, 6'b101100, 6'b110100, 6'b111100: begin // Ccc raddrhold <= pc + 1'b1; // pick up call address waddrhold <= sp - 16'h2; // place address on stack { wdatahold2, wdatahold } <= pc + 16'h3; // of address after call sp <= sp - 16'h2; // pushdown stack statesel <= `mac_call; // finish CALL // choose continue or read according to condition case (opcode[5:3]) // decode flag cases 3'b000: if (zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b001: if (!zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b010: if (carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b011: if (!carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b100: if (parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b101: if (!parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b110: if (sign) state <= `cpus_fetchi; else state <= `cpus_read; 3'b111: if (!sign) state <= `cpus_fetchi; else state <= `cpus_read; endcase pc <= pc + 16'h3; // advance after jump for false end 6'b001001: begin // RET raddrhold <= sp; // read from stack sp <= sp + 16'h2; // pushup stack statesel <= `mac_jmp; // finish JMP state <= `cpus_read; end 6'b000000, 6'b001000, 6'b010000, 6'b011000, 6'b100000, 6'b101000, 6'b110000, 6'b111000: begin // Rcc raddrhold <= sp; // read from stack sp <= sp + 16'h2; // pushup stack statesel <= `mac_jmp; // finish JMP // choose read or continue according to condition case (opcode[5:3]) // decode flag cases 3'b000: if (zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b001: if (!zero) state <= `cpus_fetchi; else state <= `cpus_read; 3'b010: if (carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b011: if (!carry) state <= `cpus_fetchi; else state <= `cpus_read; 3'b100: if (parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b101: if (!parity) state <= `cpus_fetchi; else state <= `cpus_read; 3'b110: if (sign) state <= `cpus_fetchi; else state <= `cpus_read; 3'b111: if (!sign) state <= `cpus_fetchi; else state <= `cpus_read; endcase pc <= pc+1'b1; // Next instruction byte end 6'b000111, 6'b001111, 6'b010111, 6'b011111, 6'b100111, 6'b101111, 6'b110111, 6'b111111: begin // RST pc <= opcode & 8'b00111000; // place restart value in PC waddrhold <= sp - 16'h2; // place address on stack // if interrupt cycle, use current pc, else use address // after call if (intcyc) { wdatahold2, wdatahold } <= pc; else { wdatahold2, wdatahold } <= pc + 16'h3; // cns 3 { wdatahold2, wdatahold } <= pc + 1'b1; // of address after call sp <= sp - 16'h2; // pushdown stack CNS 2 statesel <= `mac_writedbyte; // finish RST state <= `cpus_write; // write to stack end 6'b111011: begin // EI eienb <= 1'b1; // set delayed interrupt enable state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b110011: begin // DI ei <= 1'b0; state <= `cpus_fetchi; // Fetch next instruction pc <= pc+1'b1; // Next instruction byte end 6'b011011: begin // IN p raddrhold <= pc+1'b1; // pick up byte I/O address pc <= pc + 2'b10; // next statesel <= `mac_in; // finish IN state <= `cpus_read; pc <= pc + 2'b10; // Next instruction byte end 6'b010011: begin // OUT p raddrhold <= pc+1'b1; // pick up byte I/O address pc <= pc + 2'b10; // next statesel <= `mac_out; // finish OUT state <= `cpus_read; pc <= pc + 2'b10; // Next instruction byte end // the illegal opcodes behave as NOPs 6'b001011, 6'b011001, 6'b011101, 6'b101101, 6'b111101: begin state <= `cpus_fetchi; // fetch next instruction pc <= pc + 2'b10; // Next instruction byte, cns 2 end endcase end endcase end // Follow states. These state handlers implement the following cycles past // M1, or primary fetch state. // // single byte write, writes wdatahold to the waddrhold address // `cpus_write: begin addr <= waddrhold; // place address on output waddrhold <= waddrhold + 1'b1; // next address datao <= wdatahold; // set data to output wdatahold <= wdatahold2; // next data dataeno <= 1; // enable output data state <= `cpus_write2; // next state end `cpus_write2: begin // continue write #2 writemem <= 1; // enable write memory data state <= `cpus_write3; // idle one cycle for write end `cpus_write3: begin // continue write #3 if (!waitr) begin // no wait selected, otherwise cycle writemem <= 0; // disable write memory data state <= `cpus_write4; // idle hold time end end `cpus_write4: begin // continue write #4 dataeno <= 0; // disable output data state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro end // // single byte read, reads rdatahold from the raddrhold address // `cpus_read: begin addr <= raddrhold; // place address on output raddrhold <= raddrhold + 1'b1; // next address if (intcyc) inta <= 1; // activate interrupt acknowledge else readmem <= 1; // activate memory read state <= `cpus_read2; // next state end `cpus_read2: begin // continue read #2 // wait one cycle state <= `cpus_read3; // next state end `cpus_read3: begin // continue read #3 if (!waitr) begin // no wait selected, otherwise cycle rdatahold2 <= rdatahold; // shift data rdatahold <= data; // read new data readmem <= 0; // deactivate instruction memory read inta <= 0; // deactivate interrupt acknowledge state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro end end `cpus_pop: begin // finish POP instruction case (popdes) // register set 2'b00: { regfil[`reg_b], regfil[`reg_c] } <= { rdatahold, rdatahold2 }; 2'b01: { regfil[`reg_d], regfil[`reg_e] } <= { rdatahold, rdatahold2 }; 2'b10: { regfil[`reg_h], regfil[`reg_l] } <= { rdatahold, rdatahold2 }; 2'b11: begin regfil[`reg_a] <= rdatahold; sign <= ((rdatahold2 >> 7)& 1'b1) ? 1'b1:1'b0; zero <= ((rdatahold2 >> 6)& 1'b1) ? 1'b1:1'b0; auxcar <= ((rdatahold2 >> 4)& 1'b1) ? 1'b1:1'b0; parity <= ((rdatahold2 >> 2)& 1'b1) ? 1'b1:1'b0; carry <= ((rdatahold2 >> 1)& 1'b1) ? 1'b1:1'b0; end endcase state <= `cpus_fetchi; // Fetch next instruction end `cpus_jmp: begin // jump address state <= `cpus_fetchi; // and return to instruction fetch pc <= { rdatahold, rdatahold2 }; end `cpus_in: begin // input single byte to A addr <= rdatahold; // place I/O address on address lines readio <= 1; // set read I/O state <= `cpus_in2; // continue end `cpus_in2: begin // input single byte to A #2 // wait one cycle state <= `cpus_in3; // continue end `cpus_in3: begin // input single byte to A #3 if (!waitr) begin // no wait selected, otherwise cycle regfil[`reg_a] <= data; // place input data readio <= 0; // clear read I/O state <= `cpus_fetchi; // Fetch next instruction end end `cpus_out: begin // output single byte from A addr <= rdatahold; // place address on output datao <= regfil[`reg_a]; // set data to output dataeno <= 1; // enable output data state <= `cpus_out2; // next state end `cpus_out2: begin // continue out #2 writeio <= 1; // enable write I/O data state <= `cpus_out3; // idle one cycle for write end `cpus_out3: begin // continue out #3 if (!waitr) begin // no wait selected, otherwise cycle writeio <= 0; // disable write I/O data state <= `cpus_out4; // idle hold time end end `cpus_out4: begin // continue write #4 dataeno <= 0; // disable output data state <= `cpus_fetchi; // Fetch next instruction end `cpus_halt: begin // Halt waiting for interrupt // If there is an interrupt request and interrupts are enabled, then we // can leave halt. Otherwise we stay here. if (intr&&ei) state <= `cpus_fetchi; // Fetch next instruction else state <= `cpus_halt; end `cpus_movtr: begin // move to register regfil[regd] <= rdatahold; // place data state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro end `cpus_alucb: begin // alu cycleback regfil[`reg_a] <= alures; // place alu result back to A carry <= alucout; // place carry sign <= alusout; // place sign zero <= aluzout; // place zero parity <= alupar; // place parity auxcar <= aluaxc; // place auxiliary carry state <= `cpus_fetchi; // and return to instruction fetch end `cpus_indcb: begin // inr/dcr cycleback regfil[regd] <= alures; // place alu result back to source/dest sign <= alures[7]; // place sign zero <= aluzout; // place zero parity <= alupar; // place parity auxcar <= aluaxc; // place auxiliary carry state <= `cpus_fetchi; // and return to instruction fetch end `cpus_movmtbc: begin // finish LXI B regfil[`reg_b] <= rdatahold; // place upper regfil[`reg_c] <= rdatahold2; // place lower state <= `cpus_fetchi; // and return to instruction fetch end `cpus_movmtde: begin // finish LXI D regfil[`reg_d] <= rdatahold; // place upper regfil[`reg_e] <= rdatahold2; // place lower state <= `cpus_fetchi; // and return to instruction fetch end `cpus_movmthl: begin // finish LXI H regfil[`reg_h] <= rdatahold; // place upper regfil[`reg_l] <= rdatahold2; // place lower state <= `cpus_fetchi; // and return to instruction fetch end `cpus_movmtsp: begin // finish LXI SP sp <= { rdatahold, rdatahold2 }; // place state <= `cpus_fetchi; // and return to instruction fetch end `cpus_movrtw: begin // move read to write wdatahold <= rdatahold; // move read to write data state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro cns end `cpus_movrtwa: begin // move read data to write address waddrhold <= { rdatahold, rdatahold2 }; state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro cns end `cpus_movrtra: begin // move read data to read address raddrhold <= { rdatahold, rdatahold2 }; state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro cns end `cpus_lhld: begin // load HL from read data regfil[`reg_l] <= rdatahold2; // low regfil[`reg_h] <= rdatahold; // high state <= nextstate; // get next macro state statesel <= statesel+1'b1; // and index next in macro CNS end `cpus_accimm: begin aluoprb <= rdatahold; // load as alu b state <= `cpus_alucb; // go to alu cycleback end `cpus_daa: begin if (regfil[`reg_a][7:4] > 9 || carry) begin { carry, regfil[`reg_a] } <= regfil[`reg_a]+8'h60; end state <= `cpus_fetchi; // and return to instruction fetch end default: state <= 5'bx; endcase // Enable drive for data output assign data = dataeno ? datao: 8'bz; // // State macro generator // // This ROM contains series of state execution lists that perform various // tasks, usually involving reads or writes. // always @(statesel) case (statesel) // mac_writebyte: write a byte 1: nextstate = `cpus_fetchi; // fetch next instruction // mac_readbtoreg: read a byte, place in register 2: nextstate = `cpus_movtr; // move to register 3: nextstate = `cpus_fetchi; // Fetch next instruction // mac_readdtobc: read double byte to BC 4: nextstate = `cpus_read; // get high byte 5: nextstate = `cpus_movmtbc; // place in BC // mac_readdtode: read double byte to DE 6: nextstate = `cpus_read; // get high byte 7: nextstate = `cpus_movmtde; // place in DE // mac_readdtohl: read double byte to HL 8: nextstate = `cpus_read; // get high byte 9: nextstate = `cpus_movmthl; // place in HL // mac_readdtosp: read double byte to SP 10: nextstate = `cpus_read; // get high byte 11: nextstate = `cpus_movmtsp; // place in SP // mac_readbmtw: read byte and move to write 12: nextstate = `cpus_movrtw; // move read to write 13: nextstate = `cpus_fetchi; // Fetch next instruction // mac_readbmtr: read byte and move to register 14: nextstate = `cpus_movtr; // place in register 15: nextstate = `cpus_fetchi; // Fetch next instruction // mac_sta: STA 16: nextstate = `cpus_read; // read high byte 17: nextstate = `cpus_movrtwa; // move read to write address 18: nextstate = `cpus_write; // write to destination 19: nextstate = `cpus_fetchi; // Fetch next instruction // mac_lda: LDA 20: nextstate = `cpus_read; // read high byte 21: nextstate = `cpus_movrtra; // move read to write address 22: nextstate = `cpus_read; // read byte 23: nextstate = `cpus_movtr; // move to register 24: nextstate = `cpus_fetchi; // Fetch next instruction // mac_shld: SHLD 25: nextstate = `cpus_read; // read high byte 26: nextstate = `cpus_movrtwa; // move read to write address 27: nextstate = `cpus_write; // write to destination low 28: nextstate = `cpus_write; // write to destination high 29: nextstate = `cpus_fetchi; // Fetch next instruction // mac_lhld: LHLD 30: nextstate = `cpus_read; // read high byte 31: nextstate = `cpus_movrtra; // move read to write address 32: nextstate = `cpus_read; // read byte low 33: nextstate = `cpus_read; // read byte high 34: nextstate = `cpus_lhld; // move to register 35: nextstate = `cpus_fetchi; // Fetch next instruction // mac_writedbyte: write double byte 36: nextstate = `cpus_write; // double write 37: nextstate = `cpus_fetchi; // then fetch // mac_pop: POP 38: nextstate = `cpus_read; // double it 39: nextstate = `cpus_pop; // then finish // mac_xthl: XTHL 40: nextstate = `cpus_read; // double it 41: nextstate = `cpus_write; // then write 42: nextstate = `cpus_write; // double it 43: nextstate = `cpus_movmthl; // place word in hl // mac_accimm: accumulator immediate 44: nextstate = `cpus_accimm; // finish // mac_jmp: JMP 45: nextstate = `cpus_read; // double read 46: nextstate = `cpus_jmp; // then go pc // mac_call: CALL 47: nextstate = `cpus_read; // double read 48: nextstate = `cpus_write; // then write 49: nextstate = `cpus_write; // double write 50: nextstate = `cpus_jmp; // then go to that // mac_in: IN 51: nextstate = `cpus_in; // go to IN after getting that // mac_out: OUT 52: nextstate = `cpus_out; // go to OUT after getting that // mac_rst: RST 53: nextstate = `cpus_write; // double write 54: nextstate = `cpus_jmp; // then go to that default nextstate = 6'bx; // other states never reached endcase endmodule // // Alu module // // Finds arithmetic operations needed. Latches on the positive edge of the // clock. There are 8 different types of operations, which come from bits // 3-5 of the instruction. // module alu(res, opra, oprb, cin, cout, zout, sout, parity, auxcar, sel); input [7:0] opra; // Input A input [7:0] oprb; // Input B input cin; // Carry in output cout; // Carry out output zout; // Zero out output sout; // Sign out output parity; // parity output auxcar; // auxiliary carry input [2:0] sel; // Operation select output [7:0] res; // Result of alu operation reg cout; // Carry out reg zout; // Zero out reg sout; // sign out reg parity; // parity reg auxcar; // auxiliary carry reg [7:0] resi; // Result of alu operation intermediate reg [7:0] res; // Result of alu operation always @(opra, oprb, cin, sel, res, resi) begin case (sel) `aluop_add: begin // add { cout, resi } = opra+oprb; // find result and carry // auxcar = ((opra[3:0]+oprb[3:0]) >> 4) & 1'b1; // find auxiliary carry // if ((opra[3:0]+oprb[3:0])>>4) auxcar=1'b1; else auxcar=1'b0; auxcar = (((opra[3:0]+oprb[3:0]) >> 4) & 1'b1) ? 1'b1 : 1'b0 ; // find auxiliary carry end `aluop_adc: begin // adc { cout, resi } = opra+oprb+cin; // find result and carry auxcar = (((opra[3:0]+oprb[3:0]+cin) >> 4) & 1'b1) ? 1'b1 : 1'b0; // find auxiliary carry end `aluop_sub, `aluop_cmp: begin // sub/cmp { cout, resi } = opra-oprb; // find result and carry auxcar = (((opra[3:0]-oprb[3:0]) >> 4) & 1'b1) ? 1'b1 : 1'b0; // find auxiliary borrow end `aluop_sbb: begin // sbb { cout, resi } = opra-oprb-cin; // find result and carry auxcar = (((opra[3:0]-oprb[3:0]-cin >> 4)) & 1'b1) ? 1'b1 : 1'b0; // find auxiliary borrow end `aluop_and: begin // ana { cout, resi } = {1'b0, opra&oprb}; // find result and carry auxcar = 1'b0; // clear auxillary carry end `aluop_xor: begin // xra { cout, resi } = {1'b0, opra^oprb}; // find result and carry auxcar = 1'b0; // clear auxillary carry end `aluop_or: begin // ora { cout, resi } = {1'b0, opra|oprb}; // find result and carry auxcar = 1'b0; // clear auxillary carry end endcase if (sel != `aluop_cmp) res = resi; else res = opra; zout <= ~|resi; // set zero flag from result sout <= resi[7]; // set sign flag from result parity <= ~^resi; // set parity flag from result end endmodule
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