8bitworkshop/presets/verilog/sharedbuffer.v

`include "hvsync_generator.v"
`include "cpu8.v"
`include "cpu16.v"

// uncomment to see scope view
//`define DEBUG

module shared_framebuffer_top(clk, reset, hsync, vsync, hpaddle, vpaddle,
                           address_bus, to_cpu, from_cpu, write_enable
`ifdef DEBUG
                        , output [15:0] IP
                        , output carry
                        , output zero
`else
                        , rgb
`endif
);

  input clk, reset;
  input hpaddle, vpaddle;
  output hsync, vsync;
  wire display_on;
  wire [8:0] hpos;
  wire [8:0] vpos;
`ifdef DEBUG
  assign IP = cpu.regs[cpu.IP];
  assign carry = cpu.carry;
  assign zero = cpu.zero;
`else
  output [3:0] rgb;
`endif
  
  parameter IN_HPOS  = 8'b01000000;
  parameter IN_VPOS  = 8'b01000001;
  parameter IN_FLAGS = 8'b01000010;

  reg [15:0] ram[0:32767];
  reg [15:0] rom[0:1023];

  output wire [15:0] address_bus;
  output reg  [15:0] to_cpu;
  output wire [15:0] from_cpu;
  output wire write_enable;
  
  CPU16 cpu(.clk(clk),
          .reset(reset),
          .hold(hold),
          .busy(busy),
          .address(address_bus),
          .data_in(to_cpu),
          .data_out(from_cpu),
          .write(write_enable));

  always @(posedge clk)
    if (write_enable) begin
      ram[address_bus[14:0]] <= from_cpu;
    end
  
  always @(*)
    if (address_bus[15])
      to_cpu = rom[address_bus[9:0]];
    else if (&address_bus[14:8]) begin
      casez (address_bus[7:0])
        // special read registers
        IN_HPOS:  to_cpu = {8'b0, hpos[7:0]};
        IN_VPOS:  to_cpu = {8'b0, vpos[7:0]};
        IN_FLAGS: to_cpu = {11'b0, 
                            vsync, hsync, vpaddle, hpaddle, display_on};
        default:  to_cpu = 0;
      endcase
    end else
      to_cpu = ram[address_bus[14:0]];
  
  hvsync_generator hvsync_gen(
    .clk(clk),
    .reset(0),
    .hsync(hsync),
    .vsync(vsync),
    .display_on(display_on),
    .hpos(hpos),
    .vpos(vpos)
  );

  // video DMA access
  reg hold;
  wire busy;
  reg [15:0] vline[0:31]; // 32x16 bits = 256 4-color pixels
  reg [4:0] vindex;
  reg [15:0] vshift;
  //wire [15:0] scanread = scanline[hpos[7:3]];
  //wire [2:0] scanpixel = hpos[2:0];
  
  always @(posedge clk) begin
    // has CPU released the bus?
    if (busy) begin
      // write from main RAM -> scanline RAM
      vline[vindex] <= ram[{2'b10,vpos[7:0],vindex}];
      // end of scanline read?
      if (&vindex)
        hold <= 0; // release CPU
      vindex <= vindex + 1; // next address
    end else if (hpos >= 256 && hpos < 256+4 && vpos < 240) begin
      hold <= 1; // start DMA mode, hold CPU
    end else if (!hpos[8]) begin
      // load next word from vline buffer
      if (!&hpos[2:0]) begin
        vshift <= vline[vindex];
        vindex <= vindex + 1;
      end else
        vshift <= {2'b0, vshift[15:2]};
      // decode scanline RAM to RGB output
      rgb <= vshift[3:0];
    end else
      rgb <= 0;
  end

  /*
  reg [14:0] vpu_read;
  reg [15:0] vpu_buffer;
  reg [3:0]  rgb;
  
  always @(posedge clk) begin
    if (!hpos[8] && !vpos[8]) begin
      if (hpos[1:0] == 0) begin
        vpu_buffer <= ram[vpu_read];
        vpu_read <= vpu_read + 1;
      end
      //rgb <= ram[{vpos[6:0],hpos[7:0]}][3:0];
      case (hpos[1:0])
        0: rgb <= vpu_buffer[3:0];
        1: rgb <= vpu_buffer[7:4];
        2: rgb <= vpu_buffer[11:8];
        3: rgb <= vpu_buffer[15:12];
      endcase
    end else begin
      rgb <= 0;
      if (vpos[8])
        vpu_read <= 0;
    end
  end
  */

`ifdef EXT_INLINE_ASM
  initial begin
    rom = '{
        __asm
.arch femto16
.org 32768
.len 1024

.define IN_HPOS  $7f00
.define IN_VPOS  $7f01
.define IN_FLAGS $7f02

.define F_DISPLAY 1
.define F_HPADDLE 2
.define F_VPADDLE 4
.define F_HSYNC 8
.define F_VSYNC 16

Start:
      mov ax,#0
      mov bx,ax
Loop:
      mov [bx],ax
      inc bx
      inc ax
      bnz Loop
      reset
      __endasm
    };
  end
`endif
  
endmodule
more Verilog code; inline asm for depends; fixed tank 2018-02-21 19:32:11 +00:00			`include "hvsync_generator.v"
			`include "cpu8.v"
			`include "cpu16.v"

			`// uncomment to see scope view`
			//`define DEBUG

			`module shared_framebuffer_top(clk, reset, hsync, vsync, hpaddle, vpaddle,`
			`address_bus, to_cpu, from_cpu, write_enable`
			`ifdef DEBUG
			`, output [15:0] IP`
			`, output carry`
			`, output zero`
			`else
			`, rgb`
			`endif
			`);`

			`input clk, reset;`
			`input hpaddle, vpaddle;`
			`output hsync, vsync;`
			`wire display_on;`
			`wire [8:0] hpos;`
			`wire [8:0] vpos;`
			`ifdef DEBUG
			`assign IP = cpu.regs[cpu.IP];`
			`assign carry = cpu.carry;`
			`assign zero = cpu.zero;`
			`else
			`output [3:0] rgb;`
			`endif

			`parameter IN_HPOS = 8'b01000000;`
			`parameter IN_VPOS = 8'b01000001;`
			`parameter IN_FLAGS = 8'b01000010;`

			`reg [15:0] ram[0:32767];`
			`reg [15:0] rom[0:1023];`

			`output wire [15:0] address_bus;`
			`output reg [15:0] to_cpu;`
			`output wire [15:0] from_cpu;`
			`output wire write_enable;`

			`CPU16 cpu(.clk(clk),`
			`.reset(reset),`
			`.hold(hold),`
			`.busy(busy),`
			`.address(address_bus),`
			`.data_in(to_cpu),`
			`.data_out(from_cpu),`
			`.write(write_enable));`

			`always @(posedge clk)`
			`if (write_enable) begin`
			`ram[address_bus[14:0]] <= from_cpu;`
			`end`

			`always @(*)`
			`if (address_bus[15])`
			`to_cpu = rom[address_bus[9:0]];`
			`else if (&address_bus[14:8]) begin`
			`casez (address_bus[7:0])`
			`// special read registers`
			`IN_HPOS: to_cpu = {8'b0, hpos[7:0]};`
			`IN_VPOS: to_cpu = {8'b0, vpos[7:0]};`
			`IN_FLAGS: to_cpu = {11'b0,`
			`vsync, hsync, vpaddle, hpaddle, display_on};`
			`default: to_cpu = 0;`
			`endcase`
			`end else`
			`to_cpu = ram[address_bus[14:0]];`

			`hvsync_generator hvsync_gen(`
			`.clk(clk),`
			`.reset(0),`
			`.hsync(hsync),`
			`.vsync(vsync),`
			`.display_on(display_on),`
			`.hpos(hpos),`
			`.vpos(vpos)`
			`);`

			`// video DMA access`
			`reg hold;`
			`wire busy;`
			`reg [15:0] vline[0:31]; // 32x16 bits = 256 4-color pixels`
			`reg [4:0] vindex;`
			`reg [15:0] vshift;`
			`//wire [15:0] scanread = scanline[hpos[7:3]];`
			`//wire [2:0] scanpixel = hpos[2:0];`

			`always @(posedge clk) begin`
			`// has CPU released the bus?`
			`if (busy) begin`
			`// write from main RAM -> scanline RAM`
			`vline[vindex] <= ram[{2'b10,vpos[7:0],vindex}];`
			`// end of scanline read?`
			`if (&vindex)`
			`hold <= 0; // release CPU`
			`vindex <= vindex + 1; // next address`
			`end else if (hpos >= 256 && hpos < 256+4 && vpos < 240) begin`
			`hold <= 1; // start DMA mode, hold CPU`
			`end else if (!hpos[8]) begin`
			`// load next word from vline buffer`
			`if (!&hpos[2:0]) begin`
			`vshift <= vline[vindex];`
			`vindex <= vindex + 1;`
			`end else`
			`vshift <= {2'b0, vshift[15:2]};`
			`// decode scanline RAM to RGB output`
			`rgb <= vshift[3:0];`
			`end else`
			`rgb <= 0;`
			`end`

			`/*`
			`reg [14:0] vpu_read;`
			`reg [15:0] vpu_buffer;`
			`reg [3:0] rgb;`

			`always @(posedge clk) begin`
			`if (!hpos[8] && !vpos[8]) begin`
			`if (hpos[1:0] == 0) begin`
			`vpu_buffer <= ram[vpu_read];`
			`vpu_read <= vpu_read + 1;`
			`end`
			`//rgb <= ram[{vpos[6:0],hpos[7:0]}][3:0];`
			`case (hpos[1:0])`
			`0: rgb <= vpu_buffer[3:0];`
			`1: rgb <= vpu_buffer[7:4];`
			`2: rgb <= vpu_buffer[11:8];`
			`3: rgb <= vpu_buffer[15:12];`
			`endcase`
			`end else begin`
			`rgb <= 0;`
			`if (vpos[8])`
			`vpu_read <= 0;`
			`end`
			`end`
			`*/`

			`ifdef EXT_INLINE_ASM
			`initial begin`
			`rom = '{`
			`__asm`
			`.arch femto16`
			`.org 32768`
			`.len 1024`

			`.define IN_HPOS $7f00`
			`.define IN_VPOS $7f01`
			`.define IN_FLAGS $7f02`

			`.define F_DISPLAY 1`
			`.define F_HPADDLE 2`
			`.define F_VPADDLE 4`
			`.define F_HSYNC 8`
			`.define F_VSYNC 16`

			`Start:`
			`mov ax,#0`
			`mov bx,ax`
			`Loop:`
			`mov [bx],ax`
			`inc bx`
			`inc ax`
			`bnz Loop`
			`reset`
			`__endasm`
			`};`
			`end`
			`endif

			`endmodule`