RAM2GS/CPLD/RAM2GS-AGM.v
2023-08-16 21:04:05 -04:00

426 lines
15 KiB
Verilog

module RAM2GS(PHI2, MAin, CROW, Din, Dout,
nCCAS, nCRAS, nFWE, LED,
RBA, RA, RD, nRCS, RCLK, RCKE,
nRWE, nRRAS, nRCAS, RDQMH, RDQML,
nUFMCSout, UFMCLKout, UFMSDIout, UFMSDOout, In);
/* 65816 Phase 2 Clock */
input PHI2;
/* Async. DRAM Control Inputs */
input nCCAS, nCRAS;
/* Synchronized PHI2 and DRAM signals */
reg PHI2r, PHI2r2, PHI2r3;
reg RASr, RASr2, RASr3;
reg CASr, CASr2, CASr3;
reg FWEr;
reg CBR;
/* Activity LED */
reg LEDEN = 0;
output LED;
assign LED = !(!nCRAS && !CBR && LEDEN);
/* 65816 Data */
input [7:0] Din;
output [7:0] Dout;
assign Dout[7:0] = RD[7:0];
/* Latched 65816 Bank Address */
reg [7:0] Bank;
/* Async. DRAM Address Bus */
input [1:0] CROW;
input [9:0] MAin;
input nFWE;
reg n8MEGEN = 0;
reg XOR8MEG = 0;
/* SDRAM Clock */
input RCLK;
/* SDRAM */
reg RCKEEN;
output reg RCKE = 0;
output reg nRCS = 1, nRRAS = 1, nRCAS = 1, nRWE = 1;
output reg [1:0] RBA;
reg nRowColSel;
reg RA11;
reg RA10;
reg [9:0] RowA;
output [11:0] RA;
assign RA[11] = RA11;
assign RA[10] = RA10;
assign RA[9:0] = ~nRowColSel ? RowA[9:0] : MAin[9:0];
output RDQML, RDQMH;
assign RDQML = ~nRowColSel ? 1'b1 : ~MAin[9];
assign RDQMH = ~nRowColSel ? 1'b1 : MAin[9];
reg [7:0] WRD;
inout [7:0] RD;
assign RD[7:0] = (~nCCAS & ~nFWE) ? WRD[7:0] : 8'bZ;
/* UFM Interface */
reg nUFMCS = 1;
reg UFMCLK = 0;
reg UFMSDI = 0;
wire UFMSDO;
wire UFMOsc;
alta_ufms u_alta_ufms (
.i_ufm_set (1'b1),
.i_osc_ena (1'b1),
.i_ufm_flash_csn (nUFMCS),
.i_ufm_flash_sclk (UFMCLK),
.i_ufm_flash_sdi (UFMSDI),
.o_ufm_flash_sdo (UFMSDO),
.o_osc (UFMOsc)
);
/* UFM Command Interface */
reg C1Submitted = 0;
reg ADSubmitted = 0;
reg CmdEnable = 0;
reg CmdSubmitted = 0;
reg Cmdn8MEGEN = 0;
reg CmdLEDEN = 0;
reg CmdUFMCLK = 0;
reg CmdUFMSDI = 0;
reg CmdUFMCS = 0;
wire ADWR = Bank[7:0]==8'hFB & MAin[7:0]==8'hFF & ~nFWE;
wire C1WR = Bank[7:0]==8'hFB & MAin[7:0]==8'hFE & ~nFWE;
wire CMDWR = Bank[7:0]==8'hFB & MAin[7:0]==8'hFD & ~nFWE;
/* State Counters */
reg InitReady = 0; // 1 if ready for init sequence
reg Ready = 0; // 1 if done with init sequence
reg [1:0] S = 0; // post-RAS State counter
reg [17:0] FS = 0; // Fast init state counter
reg [3:0] IS = 0; // Init state counter
/* Synchronize PHI2, RAS, CAS */
always @(posedge RCLK) begin
PHI2r <= PHI2; PHI2r2 <= PHI2r; PHI2r3 <= PHI2r2;
RASr <= ~nCRAS; RASr2 <= RASr; RASr3 <= RASr2;
CASr <= ~nCCAS; CASr2 <= CASr; CASr3 <= CASr2;
end
/* Latch 65816 bank when PHI2 rises */
always @(posedge PHI2) begin
if (Ready) RA11 <= (Din[6] & ~n8MEGEN) ^ XOR8MEG; // Set RA11
else RA11 <= 1'b0; // Reserved in mode register
Bank[7:0] <= Din[7:0]; // Latch bank
end
/* Latch bank address, row address, WE, and CAS when RAS falls */
always @(negedge nCRAS) begin
if (Ready) begin
RBA[1:0] <= CROW[1:0];
RowA[9:0] <= MAin[9:0];
end else begin
RBA[1:0] <= 2'b00; // Reserved in mode register
RowA[9] <= 1'b1; // "1" for single write mode
RowA[8] <= 1'b0; // Reserved
RowA[7] <= 1'b0; // "0" for not test mode
RowA[6:4] <= 3'b010; // "2" for CAS latency 2
RowA[3] <= 1'b0; // "0" for sequential burst (not used)
RowA[2:0] <= 3'b000; // "0" for burst length 1 (no burst)
end
FWEr <= ~nFWE;
CBR <= ~nCCAS;
end
/* Latch write data when CAS falls */
always @(negedge nCCAS) begin
WRD[7:0] <= Din[7:0];
end
/* State counter from RAS */
always @(posedge RCLK) begin
if (~RASr2) S <= 0;
else if (S==2'h3) S <= 2'h3;
else S <= S+2'h1;
end
/* Init state counter */
always @(posedge RCLK) begin
// Wait ~4.178ms (at 62.5 MHz) before starting init sequence
FS <= FS+18'h1;
if (FS[17:10] == 8'hFF) InitReady <= 1'b1;
end
/* SDRAM CKE */
always @(posedge RCLK) begin
// Only 1 LUT4 allowed for this function!
RCKE <= ((RASr | RASr2) & RCKEEN) | (~RASr2 & RASr3);
end
/* SDRAM command */
always @(posedge RCLK) begin
if (Ready) begin
if (S==0) begin
if (RASr2) begin
if (CBR) begin
// AREF
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b0;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end else begin
// ACT
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // Bank RA10 consistently "1"
end
// Enable clock only for reads
RCKEEN <= ~CBR & ~FWEr;
end else if (RCKE) begin
// PCall
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b1;
nRWE <= 1'b0;
RA10 <= 1'b1; // "all"
RCKEEN <= 1'b1;
end else begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
RCKEEN <= 1'b1;
end
nRowColSel <= 1'b0; // Select registered row addres
end else if (S==1) begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
nRowColSel <= 1'b1; // Select asynchronous column address
RCKEEN <= ~CBR; // Disable clock if refresh cycle
end else if (S==2) begin
if (~FWEr & ~CBR) begin
// RD
nRCS <= 1'b0;
nRRAS <= 1'b1;
nRCAS <= 1'b0;
nRWE <= 1'b1;
RA10 <= 1'b1; // Auto-precharge
end else begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end
nRowColSel <= 1'b1; // Select asynchronous column address
RCKEEN <= ~CBR & FWEr; // Enable clock only for writes
end else if (S==3) begin
if (CASr2 & ~CASr3 & ~CBR & FWEr) begin
// WR
nRCS <= 1'b0;
nRRAS <= 1'b1;
nRCAS <= 1'b0;
nRWE <= 1'b0;
RA10 <= 1'b1; // Auto-precharge
end else begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end
nRowColSel <= ~(~FWEr | CASr3 | CBR);
RCKEEN <= ~(~FWEr | CASr2 | CBR);
end
end else if (InitReady) begin
if (S==0 & RASr2) begin
if (IS==0) begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end else if (IS==1) begin
// PC all
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b1;
nRWE <= 1'b0;
RA10 <= 1'b1; // "all"
end else if (IS==9) begin
// Load mode register
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b0;
nRWE <= 1'b0;
RA10 <= 1'b0; // Reserved in mode register
end else begin
// AREF
nRCS <= 1'b0;
nRRAS <= 1'b0;
nRCAS <= 1'b0;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end
IS <= IS+4'h1;
end else begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
end
if (S==3 & ~RASr2 & IS==15) Ready <= 1'b1;
nRowColSel <= 1'b0; // Select registered row address
RCKEEN <= 1'b1;
end else begin
// NOP
nRCS <= 1'b1;
nRRAS <= 1'b1;
nRCAS <= 1'b1;
nRWE <= 1'b1;
RA10 <= 1'b1; // RA10 is don't care
nRowColSel <= 1'b0; // Select registered row address
RCKEEN <= 1'b0;
end
end
/* Submit command when PHI2 falls */
always @(negedge PHI2) begin
// Magic number check
if (C1WR & Din[7:0]==8'hC1) begin // "C1" magic number
if (ADSubmitted) begin
CmdEnable <= 1'b1;
end
C1Submitted <= 1'b1;
ADSubmitted <= 1'b0;
end else if (ADWR & Din[7:0]==8'hAD) begin // "AD" magic number
if (C1Submitted) begin
CmdEnable <= 1'b1;
end
ADSubmitted <= 1'b1;
C1Submitted <= 1'b0;
end else if (C1WR | ADWR) begin // wrong magic number submitted
CmdEnable <= 1'b0;
C1Submitted <= 1'b0;
ADSubmitted <= 1'b0;
end else if (CMDWR) CmdEnable <= 1'b0;
// Submit command
if (CMDWR & CmdEnable) begin
// if (Din[7:4]==4'h0 && Din[3:2]==2'b00) begin // MAX w/LED
// if (Din[7:4]==4'h0) begin // MAX w/o LED
if (Din[7:4]==4'h0 && Din[3:2]==2'b01) begin // LCMXO / iCE40 / AGM
// if (Din[7:4]==4'h0 && Din[3:2]==2'b10) begin // LCMXO2
XOR8MEG <= Din[0] && !(LEDEN && Din[1]);
end else if (Din[7:4]==4'h0) begin // Unsupported type
XOR8MEG <= 0;
end else if (Din[7:4]==4'h1) begin
CmdLEDEN <= Din[1];
Cmdn8MEGEN <= ~Din[0];
CmdSubmitted <= 1'b1;
end else if (Din[7:4]==4'h2) begin
// Reserved for MAX commands
end else if (Din[7:4]==4'h3 && !Din[3]) begin
// SPI (LCMXO, iCE40, AGM) commands
CmdLEDEN <= LEDEN;
Cmdn8MEGEN <= n8MEGEN;
CmdUFMCS <= Din[2];
CmdUFMCLK <= Din[1];
CmdUFMSDI <= Din[0];
CmdSubmitted <= 1'b1;
end else if (Din[7:4]==4'h3 && Din[3]) begin
// Reserved for LCMXO2 commands
// Din[1] - Shift when high, execute when low
// Din[0] - Shift data
end
end
end
/* UFM Control */
output nUFMCSout = nUFMCS;
output UFMCLKout = UFMCLK;
output UFMSDIout = UFMSDI;
output UFMSDOout = UFMSDO;
input [3:0] In;
always @(posedge RCLK) begin
if (~InitReady && FS[17:10]==8'h00) begin
nUFMCS <= 1'b1;
UFMCLK <= 1'b0;
UFMSDI <= 1'b0;
end else if (~InitReady && FS[17:10]==8'h01) begin
nUFMCS <= 1'b0;
UFMCLK <= 1'b0;
UFMSDI <= 1'b0;
end else if (~InitReady && FS[17:10]==8'h02) begin
nUFMCS <= 1'b0;
UFMCLK <= FS[4];
case (FS[9:5]) // Shift out read data command (0x03)
5'h00: UFMSDI <= 1'b0; // command bit 7 (0)
5'h01: UFMSDI <= 1'b0; // command bit 6 (0)
5'h02: UFMSDI <= 1'b0; // command bit 5 (0)
5'h03: UFMSDI <= 1'b0; // command bit 4 (0)
5'h04: UFMSDI <= 1'b0; // command bit 3 (0)
5'h05: UFMSDI <= 1'b0; // command bit 2 (0)
5'h06: UFMSDI <= 1'b1; // command bit 1 (1)
5'h07: UFMSDI <= 1'b1; // command bit 0 (1)
5'h08: UFMSDI <= 1'b0; // address bit 23 (0)
5'h09: UFMSDI <= 1'b0; // address bit 22 (0)
5'h0A: UFMSDI <= 1'b0; // address bit 21 (0)
5'h0B: UFMSDI <= 1'b0; // address bit 20 (0)
5'h0C: UFMSDI <= 1'b0; // address bit 19 (0)
5'h0D: UFMSDI <= 1'b0; // address bit 18 (0)
5'h0E: UFMSDI <= 1'b0; // address bit 17 (0)
5'h0F: UFMSDI <= 1'b0; // address bit 16 (0)
5'h10: UFMSDI <= 1'b0; // address bit 15 (0)
5'h11: UFMSDI <= 1'b0; // address bit 14 (0)
5'h12: UFMSDI <= 1'b0; // address bit 13 (0)
5'h13: UFMSDI <= 1'b1; // address bit 12 (0)
5'h14: UFMSDI <= 1'b0; // address bit 11 (0)
5'h15: UFMSDI <= 1'b0; // address bit 10 (0)
5'h16: UFMSDI <= 1'b0; // address bit 09 (0)
5'h17: UFMSDI <= 1'b0; // address bit 08 (0)
5'h18: UFMSDI <= 1'b0; // address bit 07 (0)
5'h19: UFMSDI <= 1'b0; // address bit 06 (0)
5'h1A: UFMSDI <= 1'b0; // address bit 05 (0)
5'h1B: UFMSDI <= 1'b0; // address bit 04 (0)
5'h1C: UFMSDI <= 1'b0; // address bit 03 (0)
5'h1D: UFMSDI <= 1'b0; // address bit 02 (0)
5'h1E: UFMSDI <= 1'b0; // address bit 01 (0)
5'h1F: UFMSDI <= 1'b0; // address bit 00 (0)
endcase
end else if (~InitReady && FS[17:10]==8'h03) begin
nUFMCS <= 1'b0;
UFMCLK <= FS[4];
UFMSDI <= 1'b0;
// Latch n8MEGEN and LEDEN
if (FS[9:5]==5'h00 && FS[4:0]==5'h10) n8MEGEN <= ~UFMSDO;
if (FS[9:5]==5'h01 && FS[4:0]==5'h10) LEDEN <= ~UFMSDO;
end else if (~InitReady && FS[17:10]!=8'hFE && FS[17:10]!=8'hFF) begin
nUFMCS <= 1'b0;
UFMCLK <= FS[1];
UFMSDI <= 1'b0;
end else if (~InitReady) begin
nUFMCS <= 1'b1;
UFMCLK <= 1'b0;
UFMSDI <= 1'b0;
end else if (~PHI2r2 & PHI2r3 & CmdSubmitted) begin
// Set user command signals after PHI2 falls
LEDEN <= CmdLEDEN;
n8MEGEN <= Cmdn8MEGEN;
nUFMCS <= ~CmdUFMCS;
UFMCLK <= CmdUFMCLK;
UFMSDI <= CmdUFMSDI;
end
end
endmodule