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- module abcbus (
- input rst_n,
- input sys_clk,
- input sdram_clk, // Assumed to be a multiple of sys_clk
- input stb_1mhz, // 1-2 MHz sys_clk strobe
- // CPU interface
- input abc_valid, // Control/status registers
- input map_valid, // Memory map
- input [31:0] cpu_addr,
- input [31:0] cpu_wdata,
- input [3:0] cpu_wstrb,
- output [31:0] cpu_rdata, // For the ABC-bus control
- output [31:0] cpu_rdata_map, // For the map RAM
- output reg irq,
- // ABC bus
- input abc_clk,
- input [15:0] abc_a,
- inout [7:0] abc_d,
- output reg abc_d_oe,
- input abc_rst_n,
- input abc_cs_n,
- input [4:0] abc_out_n,
- input [1:0] abc_inp_n,
- input abc_xmemfl_n,
- input abc_xmemw800_n, // Memory write strobe (ABC800)
- input abc_xmemw80_n, // Memory write strobe (ABC80)
- input abc_xinpstb_n, // I/O read strobe (ABC800)
- input abc_xoutpstb_n, // I/O write strobe (ABC80)
- // The following are inverted versus the bus IF
- // the corresponding MOSFETs are installed
- output abc_rdy_x, // RDY = WAIT#
- output abc_resin_x, // System reset request
- output abc_int80_x, // System INT request (ABC80)
- output abc_int800_x, // System INT request (ABC800)
- output abc_nmi_x, // System NMI request (ABC800)
- output abc_xm_x, // System memory override (ABC800)
- // Host/device control
- output abc_master, // 1 = host, 0 = device
- output reg abc_a_oe,
- // Bus isolation
- output abc_d_ce_n,
- // ABC-bus extension header
- // (Note: cannot use an array here because HC and HH are
- // input only.)
- inout exth_ha,
- inout exth_hb,
- input exth_hc,
- inout exth_hd,
- inout exth_he,
- inout exth_hf,
- inout exth_hg,
- input exth_hh,
- // SDRAM interface
- output [24:0] sdram_addr,
- input [7:0] sdram_rd,
- output reg sdram_rrq,
- input sdram_rack,
- input sdram_rready,
- output [7:0] sdram_wd,
- output reg sdram_wrq,
- input sdram_wack
- );
- // Set if MOSFETs Q1-Q6 are installed rather than the corresponding
- // resistors. BOTH CANNOT BE INSTALLED AT THE SAME TIME.
- parameter [6:1] mosfet_installed = 6'b111_111;
- parameter [0:0] exth_reversed = 1'b0;
- // Synchronizer for ABC-bus input signals; also changes
- // the sense to positive logic where applicable
- wire abc_clk_s;
- wire [15:0] abc_a_s;
- wire [7:0] abc_di;
- wire abc_rst_s;
- wire abc_cs_s;
- wire [4:0] abc_out_s;
- wire [1:0] abc_inp_s;
- wire abc_xmemfl_s;
- wire abc_xmemw800_s;
- wire abc_xmemw80_s;
- wire abc_xinpstb_s;
- wire abc_xoutpstb_s;
- synchronizer #( .width(39) ) abc_synchro
- (
- .rst_n ( rst_n ),
- .clk ( clk ),
- .d ( { abc_clk, abc_a, abc_d, ~abc_rst_n, ~abc_cs_n,
- ~abc_out_n, ~abc_inp_n, ~abc_xmemfl_n, ~abc_xmemw800_n,
- ~abc_xmemw80_n, ~abc_xinpstb_n, ~abc_xoutpstb_n } ),
- .q ( { abc_clk_s, abc_a_s, abc_di, abc_rst_s, abc_cs_s,
- abc_out_s, abc_inp_s, abc_xmemfl_s, abc_xmemw800_s,
- abc_xmemw80_s, abc_xinpstb_s, abc_xoutpstb_s } )
- );
- assign abc_master = 1'b0; // Only device mode supported
- assign abc_d_ce_n = 1'b0; // Do not isolate busses
- reg abc_clk_active;
- // On ABC800, only one of XINPSTB# or XOUTPSTB# will be active;
- // on ABC80 they will either be 00 or ZZ; in the latter case pulled
- // low by external resistors.
- wire abc80 = abc_xinpstb_s & abc_xoutpstb_s;
- wire abc800 = ~abc80;
- // Memory read/write strobes
- wire abc_xmemrd = abc_clk_active & abc_xmemfl_s;
- wire abc_xmemwr = abc_clk_active &
- (abc800 ? abc_xmemw800_s : abc_xmemw80_s);
- // I/O read/write strobes for ABC-bus only
- wire [2:0] abc_inp = abc_inp_s & {3{abc_clk_active}} & {abc800, 2'b11};
- wire [4:0] abc_out = abc_out_s & {5{abc_clk_active}};
- wire abc_rst = abc_rst_s & abc_clk_active;
- wire abc_cs = abc_cs_s & abc_clk_active;
- reg [7:0] abc_do;
- assign abc_d = abc_d_oe ? abc_do : 8'hzz;
- reg [8:0] ioselx;
- wire iosel_en = ioselx[8];
- wire iosel = ioselx[5:0];
- // ABC-bus I/O select
- always @(negedge rst_n or posedge sdram_clk)
- if (~rst_n)
- ioselx <= 9'b0;
- else if (abc_rst)
- ioselx <= 9'b0;
- else if (abc_cs)
- ioselx <= { 1'b1, abc_di };
- // Open drain signals with optional MOSFETs
- wire abc_wait = 1'b0;
- wire abc_resin = ~rst_n;
- wire abc_int = 1'b0;
- wire abc_nmi = 1'b0;
- wire abc_xm = 1'b0;
- function reg opt_mosfet(input signal, input mosfet);
- if (mosfet)
- opt_mosfet = signal;
- else
- opt_mosfet = signal ? 1'b0 : 1'bz;
- endfunction // opt_mosfet
- assign abc_int80_x = opt_mosfet(abc_int & abc80, mosfet_installed[1]);
- assign abc_rdy_x = opt_mosfet(abc_wait, mosfet_installed[2]);
- assign abc_nmi_x = opt_mosfet(abc_nmi, mosfet_installed[3]);
- assign abc_resin_x = opt_mosfet(abc_resin, mosfet_installed[4]);
- assign abc_int800_x = opt_mosfet(abc_int & abc800, mosfet_installed[5]);
- assign abc_xm_x = opt_mosfet(abc_xm, mosfet_installed[6]);
- // Detect ABC-bus clock: need a minimum frequency of 84/64 MHz
- // to be considered live.
- reg [2:0] abc_clk_ctr;
- reg [1:0] abc_clk_q;
- always @(negedge rst_n or posedge sys_clk)
- if (~rst_n)
- begin
- abc_clk_q <= 2'b0;
- abc_clk_ctr <= 3'b0;
- abc_clk_active <= 1'b0;
- end
- else
- begin
- abc_clk_q <= { abc_clk_q[0], abc_clk_s };
- case ( { abc_clk_q == 2'b10, stb_1mhz } )
- 5'b10: begin
- if (abc_clk_ctr == 3'b111)
- abc_clk_active <= 1'b1;
- else
- abc_clk_ctr <= abc_clk_ctr + 1'b1;
- end
- 5'b01: begin
- if (abc_clk_ctr == 3'b000)
- abc_clk_active <= 1'b0;
- else
- abc_clk_ctr <= abc_clk_ctr - 1'b1;
- end
- default: begin
- // nothing
- end
- endcase // case ( {(abc_clk_q == 2'10), sys_clk_stb[6]} )
- end // else: !if(~rst_n)
- // ABC-bus extension header (exth_c and exth_h are input only)
- // The naming of pins is kind of nonsensical:
- //
- // +3V3 - 1 2 - +3V3
- // HA - 3 4 - HE
- // HB - 5 6 - HG
- // HC - 7 8 - HH
- // HD - 9 10 - HF
- // GND - 11 12 - GND
- //
- // This layout allows the header to be connected on either side
- // of the board. This logic assigns the following names to the pins;
- // if the ext_reversed is set to 1 then the left and right sides
- // are flipped.
- //
- // +3V3 - 1 2 - +3V3
- // exth[0] - 3 4 - exth[1]
- // exth[2] - 5 6 - exth[3]
- // exth[6] - 7 8 - exth[7]
- // exth[4] - 9 10 - exth[5]
- // GND - 11 12 - GND
- wire [7:0] exth_d; // Input data
- wire [5:0] exth_q; // Output data
- wire [5:0] exth_oe; // Output enable
- assign exth_d[0] = exth_reversed ? exth_he : exth_ha;
- assign exth_d[1] = exth_reversed ? exth_ha : exth_he;
- assign exth_d[2] = exth_reversed ? exth_hg : exth_hb;
- assign exth_d[3] = exth_reversed ? exth_hb : exth_hg;
- assign exth_d[4] = exth_reversed ? exth_hf : exth_hd;
- assign exth_d[5] = exth_reversed ? exth_hd : exth_hf;
- assign exth_d[6] = exth_reversed ? exth_hh : exth_hc;
- assign exth_d[7] = exth_reversed ? exth_hc : exth_hh;
- wire [2:0] erx = { 2'b00, exth_reversed };
- assign exth_ha = exth_oe[3'd0 ^ erx] ? exth_q[3'd0 ^ erx] : 1'bz;
- assign exth_he = exth_oe[3'd1 ^ erx] ? exth_q[3'd1 ^ erx] : 1'bz;
- assign exth_hb = exth_oe[3'd2 ^ erx] ? exth_q[3'd2 ^ erx] : 1'bz;
- assign exth_hg = exth_oe[3'd3 ^ erx] ? exth_q[3'd3 ^ erx] : 1'bz;
- assign exth_hd = exth_oe[3'd4 ^ erx] ? exth_q[3'd4 ^ erx] : 1'bz;
- assign exth_hf = exth_oe[3'd5 ^ erx] ? exth_q[3'd5 ^ erx] : 1'bz;
- assign exth_q = 6'b0;
- assign exth_oe = 6'b0;
- // ABC SDRAM interface
- //
- // Memory map for ABC-bus memory references.
- // 512 byte granularity for memory (registers 0-127),
- // one input and one output queue per select code for I/O (128-255).
- //
- // bit [24:0] = SDRAM address.
- // bit [25] = write enable ( bit 30 from CPU )
- // bit [26] = read enable ( bit 31 from CPU )
- // bit [35:27] = DMA count for I/O ( separate register 384-511 from CPU )
- //
- // Accesses from the internal CPU supports 32-bit accesses only!
- //
- // If the DMA counter is exhausted, or I/O operations other than port 0,
- // I/O is instead directed to a memory area pointed to by the iomem_base
- // register as:
- // bit [24:4] = iomem_base
- // bit [3] = read
- // bit [2:0] = port
- //
- // However, the rd and wr enable bits in the I/O map still apply.
- //
- wire [24:0] abc_memaddr;
- wire [7:0] abc_map_addr =
- abc_out_s[0] ? { 1'b1, iosel, 1'b0 } :
- abc_inp_s[0] ? { 1'b1, iosel, 1'b1 } :
- { 1'b0, abc_a_s[15:9] };
- wire [8:0] abc_dma_count;
- wire [35:0] rdata_abcmemmap;
- wire abc_rden;
- wire abc_wren;
- //
- // For I/O, don't allow the read/write enables to conflict with
- // the direction of the I/O.
- //
- wire [1:0] abcmap_masked_rdwr = cpu_wdata[31:30] &
- { ~cpu_addr[9] | ~cpu_addr[2],
- ~cpu_addr[9] | cpu_addr[2] };
- abcmapram abcmapram (
- .aclr ( ~rst_n ),
- .clock ( sdram_clk ),
- .address_a ( abc_map_addr ),
- .data_a ( { abc_dma_count - 1'b1,
- abc_rden, abc_wren,
- abc_memaddr + 1'b1 } ),
- .wren_a ( abc_dma_update ),
- .byteena_a ( 4'b1111 ),
- .q_a ( { abc_dma_count,
- abc_rden, abc_wren, abc_memaddr } ),
- .address_b ( cpu_addr[9:2] ),
- .data_b ( { cpu_wdata[8:0],
- abcmap_masked_rdwr,
- cpu_wdata[24:0] } ),
- .wren_b ( map_valid & cpu_wstrb[0] ),
- .byteena_b ( { cpu_addr[10],
- {3{~cpu_addr[10]}} } ),
- .q_b ( rdata_abcmemmap )
- );
- assign cpu_rdata_map = cpu_addr[10] ?
- { 23'b0, rdata_abcmemmap[35:27] } :
- { rdata_abcmemmap[26:25], 5'b0,
- rdata_abcmemmap[24:0] };
- reg [24:4] abc_iobase;
- reg abc_memrd_en;
- reg abc_memwr_en;
- reg abc_dma_en;
- reg abc_iowr_en;
- reg abc_iord_en;
- reg abc_do_memrd;
- reg abc_do_memwr;
- reg abc_racked;
- reg abc_wacked;
- wire abc_rack;
- wire abc_wack;
- wire abc_rready;
- // I/O status register: set on valid access, trigger IRQ.
- // The RST# (INP 7) and CS# (OUT 1) signals are always valid
- // regardless of the current select code; OUT 0/INP 0 only
- // set the bit once the DMA counter reaches zero, if applicable.
- reg [7:0] abc_inpflag;
- wire [7:0] clear_inpflag;
- reg [7:0] abc_outflag;
- wire [7:0] clear_outflag;
- always @(posedge sdram_clk or negedge rst_n)
- if (~rst_n)
- begin
- abc_memrd_en <= 1'b0;
- abc_memwr_en <= 1'b0;
- abc_dma_en <= 1'b0;
- abc_iord_en <= 1'b0;
- abc_iowr_en <= 1'b0;
- abc_do_memrd <= 1'b0;
- abc_do_memwr <= 1'b0;
- sdram_rrq <= 1'b0;
- sdram_wrq <= 1'b0;
- abc_racked <= 1'b0;
- abc_wacked <= 1'b0;
- abc_inpflag <= 8'b0;
- abc_outflag <= 8'b0;
- end
- else
- begin
- // Careful with the registering here; need to make sure
- // abcmapram is caught up
- abc_memwr_en <= abc_xmemwr;
- abc_memrd_en <= abc_xmemrd;
- abc_dma_en <= iosel_en & (abc_out[0] | abc_inp[0]);
- abc_iowr_en <= iosel_en & |abc_out;
- abc_iord_en <= iosel_en & |abc_inp;
- abc_do_memrd <= abc_rden & (abc_memrd_en | abc_iord_en);
- abc_do_memwr <= abc_wren & (abc_memwr_en | abc_iowr_en);
- abc_racked <= abc_do_memrd & (sdram_rack | abc_racked);
- abc_wacked <= abc_do_memwr & (sdram_wack | abc_wacked);
- sdram_rrq <= abc_do_memrd & ~abc_racked;
- sdram_wrq <= abc_do_memwr & ~abc_wacked;
- // This will be true for one cycle only, which is what we want
- abc_dma_update <= abc_dma_en &
- ((sdram_rrq & abc_racked) |
- (sdram_wrq & abc_wacked));
- abc_inpflag <= ~clear_inpflag &
- (abc_inpflag |
- { abc_rst, 4'b0000,
- {2{abc_iord_en}} & abc_inp[2:1],
- abc_iord_en & ~|abc_dma_count & abc_inp[0] });
- abc_outflag <= ~clear_outflag &
- (abc_outflag |
- { 2'b00, {4{abc_iowr_en}} & abc_out[4:1],
- abc_cs,
- abc_iowr_en & ~|abc_dma_count & abc_out[0] });
- end // else: !if(~rst_n)
- assign sdram_addr =
- (abc_dma_en & |abc_dma_count) ? abc_memaddr :
- (abc_iord_en|abc_iowr_en) ? { abc_iobase, |abc_inp_s, abc_a_s[2:0] } :
- { abc_memaddr[24:9], abc_a_s[8:0] };
- assign sdram_wd = abc_di;
- //
- // ABC-bus data bus handling
- //
- always @(posedge sdram_clk or negedge rst_n)
- if (~rst_n)
- begin
- abc_do <= 8'hxx;
- abc_d_oe <= 1'b0;
- end
- else if (abc_racked & sdram_rready)
- begin
- abc_do <= sdram_rd;
- abc_d_oe <= 1'b1;
- end
- else
- begin
- abc_do <= 8'hxx;
- abc_d_oe <= 1'b0;
- end
- //
- // ABC-bus control/status registers
- // All these registers are 32-bit access only except the I/O status
- // register (which is write-1-clear.)
- //
- assign clear_inpflag = {8{abc_valid & cpu_addr[5:2] == 5'b00011
- & cpu_wstrb[1]}} & cpu_wdata[15:8];
- assign clear_outflag = {8{abc_valid & cpu_addr[5:2] == 5'b00011
- & cpu_wstrb[0]}} & cpu_wdata[7:0];
- always @(posedge sys_clk or negedge rst_n)
- if (~rst_n)
- begin
- abc_iobase <= 20'bx;
- end
- else if (abc_valid & cpu_wstrb[0])
- begin
- casez (cpu_addr[5:2])
- 5'b???10:
- abc_iobase <= cpu_wdata[24:4];
- default:
- /* do nothing */ ;
- endcase
- end
- reg [31:0] abc_status[0:1];
- always @(posedge sys_clk)
- begin
- abc_status[0] <= { 29'b0, abc800, abc_rst_s, abc_clk_active };
- abc_status[1] <= abc_status[0];
- end
- wire [15:0] abc_iostatus = { abc_inpflag, abc_outflag };
- reg [15:0] abc_iostatus_q;
- always @(posedge sys_clk)
- abc_iostatus_q <= abc_iostatus;
- always_comb
- casez (cpu_addr[5:2])
- 5'b00000: cpu_rdata = abc_status[0];
- 5'b00001: cpu_rdata = ioselx[7:0];
- 5'b00010: cpu_rdata = abc_iobase;
- 5'b00011: cpu_rdata = { 16'b0, abc_iostatus };
- default: cpu_rdata = 32'bx;
- endcase // casez (cpu_addr[5:2])
- // irq is edge-triggered on either changes to abc_status
- // or bits set in iostatus.
- always @(negedge rst_n or posedge sys_clk)
- if (~rst_n)
- irq <= 1'b0;
- else
- irq <= (abc_status[1] != abc_status[0]) |
- (|(abc_iostatus & ~abc_iostatus_q));
- endmodule // abcbus
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