[firearm.git] / Memory.v

`include "ARM_Constants.v"

module Memory(
        input clk,
        input Nrst,

        input flush,

        /* bus interface */
        output reg [31:0] busaddr,
        output reg rd_req,
        output reg wr_req,
        input rw_wait,
        output reg [31:0] wr_data,
        input [31:0] rd_data,
        output reg [2:0] data_size,

        /* regfile interface */
        output reg [3:0] st_read,
        input [31:0] st_data,
        
        /* Coprocessor interface */
        output reg cp_req,
        input cp_ack,
        input cp_busy,
        output reg cp_rnw,      /* 1 = read from CP, 0 = write to CP */
        input [31:0] cp_read,
        output reg [31:0] cp_write,
        
        /* stage inputs */
        input inbubble,
        input [31:0] pc,
        input [31:0] insn,
        input [31:0] op0,
        input [31:0] op1,
        input [31:0] op2,
        input [31:0] spsr,
        input [31:0] cpsr,
        input write_reg,
        input [3:0] write_num,
        input [31:0] write_data,

        /* outputs */
        output reg outstall,
        output reg outbubble,
        output reg [31:0] outpc,
        output reg [31:0] outinsn,
        output reg out_write_reg = 1'b0,
        output reg [3:0] out_write_num = 4'bxxxx,
        output reg [31:0] out_write_data = 32'hxxxxxxxx,
        output reg [31:0] outspsr = 32'hxxxxxxxx,
        output reg [31:0] outcpsr = 32'hxxxxxxxx
        );

        reg [31:0] addr, raddr, prev_raddr, next_regdata, next_outcpsr;
        reg [31:0] prevaddr;
        reg [3:0] next_regsel, cur_reg, prev_reg;
        reg next_writeback;

        reg next_outbubble;     
        reg next_write_reg;
        reg [3:0] next_write_num;
        reg [31:0] next_write_data;

        reg [1:0] lsr_state = 2'b01, next_lsr_state;
        reg [31:0] align_s1, align_s2, align_rddata;

        reg [1:0] lsrh_state = 2'b01, next_lsrh_state;
        reg [31:0] lsrh_rddata;
        reg [15:0] lsrh_rddata_s1;
        reg [7:0] lsrh_rddata_s2;

        reg [15:0] regs, next_regs;
        reg [2:0] lsm_state = 3'b001, next_lsm_state;
        reg [5:0] offset, prev_offset, offset_sel;

        reg [31:0] swp_oldval, next_swp_oldval;
        reg [1:0] swp_state = 2'b01, next_swp_state;

        always @(posedge clk)
        begin
                outpc <= pc;
                outinsn <= insn;
                outbubble <= next_outbubble;
                out_write_reg <= next_write_reg;
                out_write_num <= next_write_num;
                out_write_data <= next_write_data;
                regs <= next_regs;
                prev_reg <= cur_reg;
                if (!rw_wait)
                        prev_offset <= offset;
                prev_raddr <= raddr;
                outcpsr <= next_outcpsr;
                outspsr <= spsr;
                swp_state <= next_swp_state;
                lsm_state <= next_lsm_state;
                lsr_state <= next_lsr_state;
                lsrh_state <= next_lsrh_state;
                prevaddr <= addr;
        end
        
        reg delayedflush = 0;
        always @(posedge clk)
                if (flush && outstall /* halp! I can't do it now, maybe later? */)
                        delayedflush <= 1;
                else if (!outstall /* anything has been handled this time around */)
                        delayedflush <= 0;

        always @(*)
        begin
                addr = prevaddr;
                raddr = 32'hxxxxxxxx;
                rd_req = 1'b0;
                wr_req = 1'b0;
                wr_data = 32'hxxxxxxxx;
                busaddr = 32'hxxxxxxxx;
                data_size = 3'bxxx;
                outstall = 1'b0;
                next_write_reg = write_reg;
                next_write_num = write_num;
                next_write_data = write_data;
                next_outbubble = inbubble;
                next_regs = regs;
                cp_req = 1'b0;
                cp_rnw = 1'bx;
                cp_write = 32'hxxxxxxxx;
                offset = prev_offset;
                next_outcpsr = lsm_state == 3'b010 ? outcpsr : cpsr;
                lsrh_rddata = 32'hxxxxxxxx;
                lsrh_rddata_s1 = 16'hxxxx;
                lsrh_rddata_s2 = 8'hxx;
                next_lsm_state = lsm_state;
                next_lsr_state = lsr_state;
                next_lsrh_state = lsrh_state;
                next_swp_oldval = swp_oldval;
                next_swp_state = swp_state;
                cur_reg = prev_reg;

                /* XXX shit not given about endianness */
                casez(insn)
                `DECODE_ALU_SWP: if(!inbubble) begin
                        outstall = rw_wait;
                        next_outbubble = rw_wait;
                        busaddr = {op0[31:2], 2'b0};
                        data_size = insn[22] ? 3'b001 : 3'b100;
                        case(swp_state)
                        2'b01: begin
                                rd_req = 1'b1;
                                outstall = 1'b1;
                                if(!rw_wait) begin
                                        next_swp_state = 2'b10;
                                        next_swp_oldval = rd_data;
                                end
                        end
                        2'b10: begin
                                wr_req = 1'b1;
                                wr_data = insn[22] ? {4{op1[7:0]}} : op1;
                                next_write_reg = 1'b1;
                                next_write_num = insn[15:12];
                                next_write_data = insn[22] ? {24'b0, swp_oldval[7:0]} : swp_oldval;
                                if(!rw_wait)
                                        next_swp_state = 2'b01;
                        end
                        default: begin end
                        endcase
                end
                `DECODE_ALU_HDATA_REG,
                `DECODE_ALU_HDATA_IMM: if(!inbubble) begin
                        next_outbubble = rw_wait;
                        outstall = rw_wait;
                        addr = insn[23] ? op0 + op1 : op0 - op1; /* up/down select */
                        raddr = insn[24] ? op0 : addr; /* pre/post increment */
                        busaddr = raddr;
                        /* rotate to correct position */
                        case(insn[6:5])
                        2'b00: begin end /* swp */
                        2'b01: begin /* unsigned half */
                                wr_data = {2{op2[15:0]}}; /* XXX need to store halfword */
                                data_size = 3'b010;
                                lsrh_rddata = {16'b0, raddr[1] ? rd_data[31:16] : rd_data[15:0]};
                        end
                        2'b10: begin /* signed byte */
                                wr_data = {4{op2[7:0]}};
                                data_size = 3'b001;
                                lsrh_rddata_s1 = raddr[1] ? rd_data[31:16] : rd_data[15:0];
                                lsrh_rddata_s2 = raddr[0] ? lsrh_rddata_s1[15:8] : lsrh_rddata_s1[7:0];
                                lsrh_rddata = {{24{lsrh_rddata_s2[7]}}, lsrh_rddata_s2};
                        end
                        2'b11: begin /* signed half */
                                wr_data = {2{op2[15:0]}};
                                data_size = 3'b010;
                                lsrh_rddata = raddr[1] ? {{16{rd_data[31]}}, rd_data[31:16]} : {{16{rd_data[15]}}, rd_data[15:0]};
                        end
                        endcase

                        case(lsrh_state)
                        2'b01: begin
                                rd_req = insn[20];
                                wr_req = ~insn[20];
                                next_write_num = insn[15:12];
                                next_write_data = lsrh_rddata;
                                if(insn[20]) begin
                                        next_write_reg = 1'b1;
                                end
                                if(insn[21] | !insn[24]) begin
                                        outstall = 1'b1;
                                        if(!rw_wait)
                                                next_lsrh_state = 2'b10;
                                end
                        end
                        2'b10: begin
                                next_write_reg = 1'b1;
                                next_write_num = insn[19:16];
                                next_write_data = addr;
                                next_lsrh_state = 2'b10;
                        end
                        default: begin end
                        endcase
                end
                `DECODE_LDRSTR_UNDEFINED: begin end
                `DECODE_LDRSTR: if(!inbubble) begin
                        next_outbubble = rw_wait;
                        outstall = rw_wait;
                        addr = insn[23] ? op0 + op1 : op0 - op1; /* up/down select */
                        raddr = insn[24] ? addr : op0; /* pre/post increment */
                        busaddr = raddr;
                        /* rotate to correct position */
                        align_s1 = raddr[1] ? {rd_data[15:0], rd_data[31:16]} : rd_data;
                        align_s2 = raddr[0] ? {align_s1[7:0], align_s1[31:8]} : align_s1;
                        /* select byte or word */
                        align_rddata = insn[22] ? {24'b0, align_s2[7:0]} : align_s2;
                        wr_data = insn[22] ? {4{op2[7:0]}} : op2; /* XXX need to actually store just a byte */
                        data_size = insn[22] ? 3'b001 : 3'b100;
                        case(lsr_state)
                        2'b01: begin
                                rd_req = insn[20];
                                wr_req = ~insn[20];
                                next_write_reg = 1'b1;
                                next_write_num = insn[15:12];
                                if(insn[20]) begin
                                        next_write_data = align_rddata;
                                end
                                if(insn[21] | !insn[24]) begin
                                        outstall = 1'b1;
                                        if(!rw_wait)
                                                next_lsr_state = 2'b10;
                                end
                                $display("LDRSTR: rd_req %d, wr_req %d, raddr %08x, wait %d", rd_req, wr_req, raddr, rw_wait);
                        end
                        2'b10: begin
                                next_write_reg = 1'b1;
                                next_write_num = insn[19:16];
                                next_write_data = addr;
                                next_lsr_state = 2'b01;
                        end
                        default: begin end
                        endcase
                end
                /* XXX ldm/stm incorrect in that stupid case where one of the listed regs is the base reg */
                `DECODE_LDMSTM: if(!inbubble) begin
                        outstall = rw_wait;
                        next_outbubble = rw_wait;
                        data_size = 3'b100;
                        case(lsm_state)
                        3'b001: begin
//                              next_regs = insn[23] ? op1[15:0] : op1[0:15];
                                /** verilator can suck my dick */
                                $display("LDMSTM: Round 1: base register: %08x, reg list %b", op0, op1[15:0]);
                                next_regs = insn[23] /* U */ ? op1[15:0] : {op1[0], op1[1], op1[2], op1[3], op1[4], op1[5], op1[6], op1[7],
                                                                            op1[8], op1[9], op1[10], op1[11], op1[12], op1[13], op1[14], op1[15]};
                                offset = 6'b0;
                                outstall = 1'b1;
                                next_lsm_state = 3'b010;
                        end
                        3'b010: begin
                                rd_req = insn[20];
                                wr_req = ~insn[20];
                                casez(regs)
                                16'b???????????????1: begin
                                        cur_reg = 4'h0;
                                        next_regs = {regs[15:1], 1'b0};
                                end
                                16'b??????????????10: begin
                                        cur_reg = 4'h1;
                                        next_regs = {regs[15:2], 2'b0};
                                end
                                16'b?????????????100: begin
                                        cur_reg = 4'h2;
                                        next_regs = {regs[15:3], 3'b0};
                                end
                                16'b????????????1000: begin
                                        cur_reg = 4'h3;
                                        next_regs = {regs[15:4], 4'b0};
                                end
                                16'b???????????10000: begin
                                        cur_reg = 4'h4;
                                        next_regs = {regs[15:5], 5'b0};
                                end
                                16'b??????????100000: begin
                                        cur_reg = 4'h5;
                                        next_regs = {regs[15:6], 6'b0};
                                end
                                16'b?????????1000000: begin
                                        cur_reg = 4'h6;
                                        next_regs = {regs[15:7], 7'b0};
                                end
                                16'b????????10000000: begin
                                        cur_reg = 4'h7;
                                        next_regs = {regs[15:8], 8'b0};
                                end
                                16'b???????100000000: begin
                                        cur_reg = 4'h8;
                                        next_regs = {regs[15:9], 9'b0};
                                end
                                16'b??????1000000000: begin
                                        cur_reg = 4'h9;
                                        next_regs = {regs[15:10], 10'b0};
                                end
                                16'b?????10000000000: begin
                                        cur_reg = 4'hA;
                                        next_regs = {regs[15:11], 11'b0};
                                end
                                16'b????100000000000: begin
                                        cur_reg = 4'hB;
                                        next_regs = {regs[15:12], 12'b0};
                                end
                                16'b???1000000000000: begin
                                        cur_reg = 4'hC;
                                        next_regs = {regs[15:13], 13'b0};
                                end
                                16'b??10000000000000: begin
                                        cur_reg = 4'hD;
                                        next_regs = {regs[15:14], 14'b0};
                                end
                                16'b?100000000000000: begin
                                        cur_reg = 4'hE;
                                        next_regs = {regs[15], 15'b0};
                                end
                                16'b1000000000000000: begin
                                        cur_reg = 4'hF;
                                        next_regs = 16'b0;
                                end
                                default: begin
                                        cur_reg = 4'hx;
                                        next_regs = 16'b0;
                                end
                                endcase
                                cur_reg = insn[23] ? cur_reg : 4'hF - cur_reg;
                                if(cur_reg == 4'hF && insn[22]) begin
                                        next_outcpsr = spsr;
                                end

                                offset = prev_offset + 6'h4;
                                offset_sel = insn[24] ? offset : prev_offset;
                                raddr = insn[23] ? op0 + {26'b0, offset_sel} : op0 - {26'b0, offset_sel};
                                if(insn[20]) begin
                                        next_write_reg = !rw_wait;
                                        next_write_num = cur_reg;
                                        next_write_data = rd_data;
                                end
                                if (rw_wait) begin
                                        next_regs = regs;
                                        cur_reg = prev_reg;     /* whoops, do this one again */
                                end

                                st_read = cur_reg;
                                wr_data = (cur_reg == 4'hF) ? (pc + 12) : st_data;
                                busaddr = raddr;
                                
                                $display("LDMSTM: Stage 2: Writing: regs %b, next_regs %b, reg %d, wr_data %08x, addr %08x", regs, next_regs, cur_reg, wr_data, busaddr);

                                outstall = 1'b1;

                                if(next_regs == 16'b0) begin
                                        next_lsm_state = 3'b100;
                                end
                        end
                        3'b100: begin
                                next_write_reg = insn[21] /* writeback */;
                                next_write_num = insn[19:16];
                                next_write_data = insn[23] ? op0 + {26'b0, prev_offset} : op0 - {26'b0, prev_offset};
                                next_lsm_state = 3'b001;
                                $display("LDMSTM: Stage 3: Writing back");
                        end
                        default: $stop;
                        endcase
                        $display("LDMSTM: Decoded, bubble %d, insn %08x, lsm state %b -> %b, stall %d", inbubble, insn, lsm_state, next_lsm_state, outstall);
                end
                `DECODE_LDCSTC: if(!inbubble) begin
                        $display("WARNING: Unimplemented LDCSTC");
                end
                `DECODE_CDP: if(!inbubble) begin
                        cp_req = 1;
                        if (cp_busy) begin
                                outstall = 1;
                                next_outbubble = 1;
                        end
                        if (!cp_ack) begin
                                /* XXX undefined instruction trap */
                                $display("WARNING: Possible CDP undefined instruction");
                        end
                end
                `DECODE_MRCMCR: if(!inbubble) begin
                        cp_req = 1;
                        cp_rnw = insn[20] /* L */;
                        if (insn[20] == 0 /* store to coprocessor */)
                                cp_write = op0;
                        else begin
                                if (insn[15:12] != 4'hF /* Fuck you ARM */) begin
                                        next_write_reg = 1'b1;
                                        next_write_num = insn[15:12];
                                        next_write_data = cp_read;
                                end else
                                        next_outcpsr = {cp_read[31:28], cpsr[27:0]};
                        end
                        if (cp_busy) begin
                                outstall = 1;
                                next_outbubble = 1;
                        end
                        if (!cp_ack) begin
                                $display("WARNING: Possible MRCMCR undefined instruction: cp_ack %d, cp_busy %d",cp_ack, cp_busy);
                        end
                        $display("MRCMCR: ack %d, busy %d", cp_ack, cp_busy);
                end
                default: begin end
                endcase
                
                if ((flush || delayedflush) && !outstall)
                        next_outbubble = 1'b1;
        end
endmodule