forked from Apple-2-HW/GR8RAM
223 lines
7.4 KiB
Verilog
Executable File
223 lines
7.4 KiB
Verilog
Executable File
module GR8RAM(C7M, C7M_2, Q3, PHI0in, PHI1in, nRES, MODE,
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A, RA, nWE, D, RD, nINH,
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nDEVSEL, nIOSEL, nIOSTRB,
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nRAS, nCAS0, nCAS1, nRCS, nROE, nRWE);
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/* Clock, Reset, Mode */
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input C7M, C7M_2, Q3, PHI0in, PHI1in; // Clock inputs
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input nRES, MODE; // Reset, mode
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/* PHI1 Delay */
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wire [8:0] PHI1b;
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wire PHI1;
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LCELL PHI1b0_MC (.in(PHI1in), .out(PHI1b[0]));
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LCELL PHI1b1_MC (.in(PHI1b[0]), .out(PHI1b[1]));
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LCELL PHI1b2_MC (.in(PHI1b[1]), .out(PHI1b[2]));
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LCELL PHI1b3_MC (.in(PHI1b[2]), .out(PHI1b[3]));
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LCELL PHI1b4_MC (.in(PHI1b[3]), .out(PHI1b[4]));
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LCELL PHI1b5_MC (.in(PHI1b[4]), .out(PHI1b[5]));
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LCELL PHI1b6_MC (.in(PHI1b[5]), .out(PHI1b[6]));
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LCELL PHI1b7_MC (.in(PHI1b[6]), .out(PHI1b[7]));
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LCELL PHI1b8_MC (.in(PHI1b[7]), .out(PHI1b[8]));
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LCELL PHI1b9_MC (.in(PHI1b[8] & PHI1in), .out(PHI1));
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/* Address Bus, etc. */
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input nDEVSEL, nIOSEL, nIOSTRB; // Card select signals
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input [15:0] A; // 6502 address bus
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input nWE; // 6502 R/W
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output [10:0] RA; // DRAM/ROM address
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assign RA[10:8] = ASel ? Addr[21:19] : Addr[10:8];
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assign RA[7:0] = (~nIOSTRB & FullIOEN) ? Bank+1 :
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(~nIOSTRB & ~FullIOEN) ? {7'b0000001, Bank[0]} :
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(~ASel & nIOSEL & nIOSTRB) ? Addr[18:11] :
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(ASel & nIOSEL & nIOSTRB) ? Addr[7:0] : 8'h00;
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/* Data Bus Routing */
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// DRAM/ROM data bus
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wire RDOE = CSDBEN & ~nWE;
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inout [7:0] RD = RDOE ? D[7:0] : 8'bZ;
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// Apple II data bus
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wire DOE = CSDBEN & nWE &
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((~nDEVSEL & REGEN) | ~nIOSEL | (~nIOSTRB & IOROMEN));
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wire [7:0] Dout = (nDEVSEL | RAMSELA) ? RD[7:0] :
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AddrHSELA ? {1'b1, Addr[22:16]} :
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AddrMSELA ? Addr[15:8] :
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AddrLSELA ? Addr[7:0] : 8'h00;
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inout [7:0] D = DOE ? Dout : 8'bZ;
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/* Inhibit output */
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wire AROMSEL;
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LCELL AROMSEL_MC (.in(/*(A[15:12]==4'hD | A[15:12]==4'hE | A[15:12]==4'hF) & nWE & ~MODE*/0), .out(AROMSEL));
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output nINH = AROMSEL ? 1'b0 : 1'bZ;
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/* DRAM and ROM Control Signals */
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output nRCS = ~((~nIOSEL | (~nIOSTRB & IOROMEN)) & CSDBEN); // ROM chip select
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output nROE = ~nWE; // need this for flash ROM
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output nRWE = nWE | (nDEVSEL & nIOSEL & nIOSTRB); // for ROM & DRAM
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output nRAS = ~(RASr | RASf);
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output nCAS0 = ~(CASr | (CASf & RAMSEL & ~Addr[22])); // DRAM CAS bank 0
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output nCAS1 = ~(CASr | (CASf & RAMSEL & Addr[22])); // DRAM CAS bank 1
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/* 6502-accessible Registers */
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reg [7:0] Bank = 8'h00; // Bank register for ROM access
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reg [22:0] Addr = 23'h00000; // RAM address register
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/* Increment Control */
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reg IncAddrL = 0, IncAddrM = 0, IncAddrH = 0;
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/* CAS rising/falling edge components */
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// These are combined to create the CAS outputs.
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reg CASr = 1'b0;
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reg CASf = 1'b0;
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reg RASr = 1'b0;
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reg RASf = 1'b0;
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/* State Counters */
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reg PHI1reg = 1'b0; // Saved PHI1 at last rising clock edge
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reg PHI0seen = 1'b0; // Have we seen PHI0 since reset?
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reg [2:0] S = 3'h0; // State counter
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reg [3:0] Ref = 4'h0; // Refresh skip counter
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/* Select Signals */
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wire BankSELA = A[3:0]==4'hF;
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wire SetSELA = A[3:0]==4'hE;
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wire RAMSELA = A[3:0]==4'h3;
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wire AddrHSELA = A[3:0]==4'h2;
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wire AddrMSELA = A[3:0]==4'h1;
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wire AddrLSELA = A[3:0]==4'h0;
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LCELL BankWR_MC (.in(BankSELA & ~nWE & ~nDEVSEL & REGEN), .out(BankWR)); wire BankWR;
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wire SetWR = SetSELA & ~nWE & ~nDEVSEL & REGEN;
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LCELL RAMSEL_MC (.in(RAMSELA & ~nDEVSEL & REGEN), .out(RAMSEL)); wire RAMSEL;
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LCELL AddrHWR_MC (.in(AddrHSELA & ~nWE & ~nDEVSEL & REGEN), .out(AddrHWR)); wire AddrHWR;
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LCELL AddrMWR_MC (.in(AddrMSELA & ~nWE & ~nDEVSEL & REGEN), .out(AddrMWR)); wire AddrMWR;
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LCELL AddrLWR_MC (.in(AddrLSELA & ~nWE & ~nDEVSEL & REGEN), .out(AddrLWR)); wire AddrLWR;
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/* Misc. */
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reg REGEN = 0; // Register enable
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reg IOROMEN = 0; // IOSTRB ROM enable
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reg CSDBEN = 0; // ROM CS, data bus driver gating
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reg ASel = 0; // DRAM address multiplexer select
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reg FullIOEN = 0;
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// Apple II Bus Compatibiltiy Rules:
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// Synchronize to PHI0 or PHI1. (PHI1 here)
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// PHI1's edge may be -20ns,+10ns relative to C7M.
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// Delay the rising edge of PHI1 to get enough hold time:
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// PHI1modified = PHI1 & PHI1delayed;
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// Only sample /DEVSEL, /IOSEL at these times:
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// 2nd and 3rd rising edge of C7M in PHI0 (S4, S5)
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// all 3 falling edges of C7M in PHI0 (S4, S5, S6)
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// Can sample /IOSTRB at same times as /IOSEL, plus:
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// 1st rising edge of C7M in PHI0 (S3)
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always @(posedge C7M, negedge nRES) begin
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if (~nRES) begin // Reset
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PHI1reg <= 1'b0;
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PHI0seen <= 1'b0;
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S <= 3'h0;
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Ref <= 3'b000;
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REGEN <= 1'b0;
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IOROMEN <= 1'b0;
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CSDBEN <= 1'b0;
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end else begin
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// Synchronize state counter to S1 when just entering PHI1
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PHI1reg <= PHI1; // Save old PHI1
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if (~PHI1) PHI0seen <= 1; // PHI0seen set in PHI0
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S <= (PHI1 & ~PHI1reg & PHI0seen) ? 4'h1 :
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S==0 ? 3'h0 :
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S==7 ? 3'h7 : S+1;
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// Refresh counter allows DRAM refresh once every 13 cycles
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if (S==3) Ref <= (Ref[3:2] == 2'b11) ? 4'h0 : Ref+1;
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// Disable IOSTRB ROM when accessing 0xCFFF.
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if (S==3 & ~nIOSTRB & A[10:0]==11'h7FF) IOROMEN <= 1'b0;
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// Registers enabled at end of S4 by any IOSEL access (Cn00-CnFF).
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if (S==4 & ~nIOSEL) REGEN <= 1;
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// Enable IOSTRB ROM when accessing CnXX in IOSEL ROM.
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if (S==4 & ~nIOSEL) IOROMEN <= 1'b1;
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// Only drive Apple II data bus after state 4 to avoid bus fight.
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// Thus we wait 1.5 7M cycles (210 ns) into PHI0 before driving.
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// Same for driving the ROM/SRAM data bus (RD).
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// Similarly, only select the ROM chip starting at the end of S4.
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// This provides address setup time for write operations and
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// minimizes power consumption.
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CSDBEN <= S==4 | S==5 | S==6 | S==7;
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end
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end
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always @(negedge C7M, negedge nRES) begin
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if (~nRES) begin
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Addr <= 23'h000000;
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Bank <= 8'h00;
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FullIOEN <= 1'b0;
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IncAddrL <= 1'b0;
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IncAddrM <= 1'b0;
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IncAddrH <= 1'b0;
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end else begin
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// Increment address register
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if (S==1 & IncAddrL) begin
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Addr[7:0] <= Addr[7:0]+1;
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IncAddrL <= 0;
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IncAddrM <= Addr[7:0] == 8'hFF;
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end
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if (S==2 & IncAddrM) begin
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Addr[15:8] <= Addr[15:8]+1;
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IncAddrM <= 0;
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IncAddrH <= Addr[15:8] == 8'hFF;
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end
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if (S==3 & IncAddrH) begin
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IncAddrH <= 0;
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Addr[22:16] <= Addr[22:16]+1;
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end
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// Set register during S6 if accessed.
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if (S==6) begin
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if (BankWR) Bank[7:0] <= D[7:0]; // Bank
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if (SetWR) FullIOEN <= D[7:0] == 8'hE5;
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IncAddrL <= RAMSEL;
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IncAddrM <= AddrLWR & Addr[7] & ~D[7];
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IncAddrH <= AddrMWR & Addr[15] & ~D[7];
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if (AddrHWR) Addr[22:16] <= D[6:0]; // Addr hi
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if (AddrMWR) Addr[15:8] <= D[7:0]; // Addr mid
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if (AddrLWR) Addr[7:0] <= D[7:0]; // Addr lo
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end
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end
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end
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/* DRAM RAS/CAS */
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always @(posedge C7M, negedge nRES) begin
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if (~nRES) begin RASr <= 1'b0; CASr <= 1'b0; ASel <= 1'b0;
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end else begin
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// RAS already asserted in middle of S4,
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// so hold RAS through S5
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RASr <= (S==4 & RAMSEL);
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// Multiplex DRAM address in at end of S4 through S6.
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ASel = RAMSEL & (S==4 | S==5);
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// Refresh at end of S1 (i.e. through S2)
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// CAS whenever RAM seleced
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CASr <= (S==1 & Ref==0) | (S==5 & RAMSEL);
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end
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end
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always @(negedge C7M_2, negedge nRES) begin
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if (~nRES) begin RASf <= 1'b0; CASf <= 1'b0;
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end else begin
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// Refresh in S2
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// Row activate in S4 when accessing RAM
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// Hold RAS in S5 when not doing late CAS for write.
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RASf <= (S==2 & Ref==0) | (RAMSEL & (S==4 | (S==5 /*& ~nWE*/)));
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// CASf gated by nDEVSEL; no need to predicate on RAMSEL.
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// Early CAS in S5 for read operations.
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CASf <= (S==5 & nWE) | (S==6) | (S==7);
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end
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end
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endmodule
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