//============================================================================ // Acorn Archimedes // // Port to MiSTer. // Copyright (C) 2017-2019 Sorgelig // // This program is free software; you can redistribute it and/or modify it // under the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 of the License, or (at your option) // any later version. // // This program is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for // more details. // // You should have received a copy of the GNU General Public License along // with this program; if not, write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. //============================================================================ module emu ( //Master input clock input CLK_50M, //Async reset from top-level module. //Can be used as initial reset. input RESET, //Must be passed to hps_io module inout [48:0] HPS_BUS, //Base video clock. Usually equals to CLK_SYS. output CLK_VIDEO, //Multiple resolutions are supported using different CE_PIXEL rates. //Must be based on CLK_VIDEO output CE_PIXEL, //Video aspect ratio for HDMI. Most retro systems have ratio 4:3. //if VIDEO_ARX[12] or VIDEO_ARY[12] is set then [11:0] contains scaled size instead of aspect ratio. output [12:0] VIDEO_ARX, output [12:0] VIDEO_ARY, output [7:0] VGA_R, output [7:0] VGA_G, output [7:0] VGA_B, output VGA_HS, output VGA_VS, output VGA_DE, // = ~(VBlank | HBlank) output VGA_F1, output [1:0] VGA_SL, output VGA_SCALER, // Force VGA scaler output VGA_DISABLE, // analog out is off input [11:0] HDMI_WIDTH, input [11:0] HDMI_HEIGHT, output HDMI_FREEZE, output HDMI_BLACKOUT, output HDMI_BOB_DEINT, `ifdef MISTER_FB // Use framebuffer in DDRAM // FB_FORMAT: // [2:0] : 011=8bpp(palette) 100=16bpp 101=24bpp 110=32bpp // [3] : 0=16bits 565 1=16bits 1555 // [4] : 0=RGB 1=BGR (for 16/24/32 modes) // // FB_STRIDE either 0 (rounded to 256 bytes) or multiple of pixel size (in bytes) output FB_EN, output [4:0] FB_FORMAT, output [11:0] FB_WIDTH, output [11:0] FB_HEIGHT, output [31:0] FB_BASE, output [13:0] FB_STRIDE, input FB_VBL, input FB_LL, output FB_FORCE_BLANK, `ifdef MISTER_FB_PALETTE // Palette control for 8bit modes. // Ignored for other video modes. output FB_PAL_CLK, output [7:0] FB_PAL_ADDR, output [23:0] FB_PAL_DOUT, input [23:0] FB_PAL_DIN, output FB_PAL_WR, `endif `endif output LED_USER, // 1 - ON, 0 - OFF. // b[1]: 0 - LED status is system status OR'd with b[0] // 1 - LED status is controled solely by b[0] // hint: supply 2'b00 to let the system control the LED. output [1:0] LED_POWER, output [1:0] LED_DISK, // I/O board button press simulation (active high) // b[1]: user button // b[0]: osd button output [1:0] BUTTONS, input CLK_AUDIO, // 24.576 MHz output [15:0] AUDIO_L, output [15:0] AUDIO_R, output AUDIO_S, // 1 - signed audio samples, 0 - unsigned output [1:0] AUDIO_MIX, // 0 - no mix, 1 - 25%, 2 - 50%, 3 - 100% (mono) //ADC inout [3:0] ADC_BUS, //SD-SPI output SD_SCK, output SD_MOSI, input SD_MISO, output SD_CS, input SD_CD, //High latency DDR3 RAM interface //Use for non-critical time purposes output DDRAM_CLK, input DDRAM_BUSY, output [7:0] DDRAM_BURSTCNT, output [28:0] DDRAM_ADDR, input [63:0] DDRAM_DOUT, input DDRAM_DOUT_READY, output DDRAM_RD, output [63:0] DDRAM_DIN, output [7:0] DDRAM_BE, output DDRAM_WE, //SDRAM interface with lower latency output SDRAM_CLK, output SDRAM_CKE, output [12:0] SDRAM_A, output [1:0] SDRAM_BA, inout [15:0] SDRAM_DQ, output SDRAM_DQML, output SDRAM_DQMH, output SDRAM_nCS, output SDRAM_nCAS, output SDRAM_nRAS, output SDRAM_nWE, `ifdef MISTER_DUAL_SDRAM //Secondary SDRAM //Set all output SDRAM_* signals to Z ASAP if SDRAM2_EN is 0 input SDRAM2_EN, output SDRAM2_CLK, output [12:0] SDRAM2_A, output [1:0] SDRAM2_BA, inout [15:0] SDRAM2_DQ, output SDRAM2_nCS, output SDRAM2_nCAS, output SDRAM2_nRAS, output SDRAM2_nWE, `endif input UART_CTS, output UART_RTS, input UART_RXD, output UART_TXD, output UART_DTR, input UART_DSR, // Open-drain User port. // 0 - D+/RX // 1 - D-/TX // 2..6 - USR2..USR6 // Set USER_OUT to 1 to read from USER_IN. input [6:0] USER_IN, output [6:0] USER_OUT, input OSD_STATUS ); assign ADC_BUS = 'Z; assign USER_OUT = '1; assign {UART_RTS, UART_TXD, UART_DTR} = 0; assign {DDRAM_CLK, DDRAM_BURSTCNT, DDRAM_ADDR, DDRAM_DIN, DDRAM_BE, DDRAM_RD, DDRAM_WE} = 0; assign {SD_SCK, SD_MOSI, SD_CS} = 'Z; assign LED_USER = fdd_led; assign LED_DISK = hdd_led; assign LED_POWER = 0; assign BUTTONS = 0; assign HDMI_FREEZE = 0; assign HDMI_BLACKOUT = 0; assign HDMI_BOB_DEINT = 0; assign VGA_DISABLE = 0; wire vga_de; video_freak video_freak ( .*, .VGA_DE_IN(vga_de), .ARX((!status[7:6]) ? 8'd4 : (status[7:6] - 1'd1)), .ARY((!status[7:6]) ? 8'd3 : 8'd0), .CROP_SIZE(0), .CROP_OFF(0), .SCALE(status[9:8]) ); `include "build_id.v" localparam CONF_STR = { "ARCHIE;;", "J,Fire;", "V,v",`BUILD_DATE }; //////////////////// CLOCKS /////////////////// wire pll_ready; wire clk_mem; wire clk_sys; pll pll ( .refclk(CLK_50M), .outclk_0(clk_mem), .outclk_1(clk_sys), .locked(pll_ready) ); reg initReset_n = 0; always @(posedge clk_sys) if(riscos_dl) initReset_n <= 1; wire reset = status[0] | buttons[1] | RESET | ~initReset_n | riscos_dl; ////////////////// HPS I/O /////////////////// wire [15:0] joyA; wire [15:0] joyB; wire [1:0] buttons; wire [31:0] status; wire [7:0] kbd_out_data; wire kbd_out_strobe; wire [7:0] kbd_in_data; wire kbd_in_strobe; wire ioctl_download; wire [7:0] ioctl_index; wire ioctl_wr; wire [24:0] ioctl_addr; wire [15:0] ioctl_dout; wire [15:0] ioctl_din; reg ioctl_wait = 0; wire [31:0] sd_lba; wire [1:0] sd_rd; wire [1:0] sd_wr; wire [1:0] sd_ack; wire [7:0] sd_buff_addr; wire [15:0] sd_buff_dout; wire [15:0] sd_buff_din; wire sd_buff_wr; wire [1:0] img_mounted; wire [31:0] img_size; wire img_readonly; wire [21:0] gamma_bus; hps_io #(.CONF_STR(CONF_STR), .WIDE(1), .VDNUM(2)) hps_io ( .clk_sys(clk_sys), .HPS_BUS(HPS_BUS), .joystick_0(joyA), .joystick_1(joyB), .buttons(buttons), .status(status), .new_vmode(new_vmode), .gamma_bus(gamma_bus), .ioctl_index(ioctl_index), .ioctl_download(ioctl_download), .ioctl_addr(ioctl_addr), .ioctl_dout(ioctl_dout), .ioctl_wr(ioctl_wr), .ioctl_wait(ioctl_wait|loader_stb), .ioctl_din(ioctl_din), .sd_lba('{sd_lba,sd_lba}), .sd_rd(sd_rd), .sd_wr(sd_wr), .sd_ack(sd_ack), .sd_buff_addr(sd_buff_addr), .sd_buff_dout(sd_buff_dout), .sd_buff_din('{sd_buff_din,sd_buff_din}), .sd_buff_wr(sd_buff_wr), .img_mounted(img_mounted), .img_size(img_size), .img_readonly(img_readonly), .EXT_BUS(EXT_BUS) ); wire [35:0] EXT_BUS; hps_ext hps_ext ( .clk_sys ( clk_sys ), .EXT_BUS ( EXT_BUS ), .kbd_out_data ( kbd_out_data ), .kbd_out_strobe ( kbd_out_strobe ), .kbd_in_data ( kbd_in_data ), .kbd_in_strobe ( kbd_in_strobe ), .cmos_cnt ( cmos_cnt ), .ide_req ( ide_req ), .ide_addr ( ide_address ), .ide_wr ( ide_write ), .ide_dout ( ide_writedata ), .ide_rd ( ide_read ), .ide_din ( ide_readdata ) ); assign AUDIO_S = 1; assign AUDIO_MIX = status[3:2]; wire [3:0] core_r, core_g, core_b; wire core_hs, core_vs, core_de; wire core_ack_in; wire core_stb_out; wire core_cyc_out; wire core_we_o; wire [3:0] core_sel_o; wire [2:0] core_cti_o; wire [31:0] core_data_in, core_data_out; wire [31:0] ram_data_in; wire [23:2] core_address_out; wire [1:0] pixbaseclk_select; wire [1:0] selpix; wire i2c_din, i2c_dout, i2c_clock; wire [5:0] ide_req; wire [4:0] ide_address; wire ide_write; wire [15:0] ide_writedata; wire ide_read; wire [15:0] ide_readdata; wire fdd_led; wire hdd_led; archimedes_top #(CLKSYS) ARCHIMEDES ( .CLKCPU_I ( clk_sys ), .CLKPIX_I ( CLK_VIDEO ), .CEPIX_I ( CE_PIXEL ), .SELPIX_O ( selpix ), .CEAUD_I ( ceaud ), .RESET_I (~ram_ready | reset), .MEM_ACK_I ( core_ack_in ), .MEM_DAT_I ( core_data_in ), .MEM_DAT_O ( core_data_out ), .MEM_ADDR_O ( core_address_out), .MEM_STB_O ( core_stb_out ), .MEM_CYC_O ( core_cyc_out ), .MEM_SEL_O ( core_sel_o ), .MEM_WE_O ( core_we_o ), .MEM_CTI_O ( core_cti_o ), .HSYNC ( core_hs ), .VSYNC ( core_vs ), .VIDEO_R ( core_r ), .VIDEO_G ( core_g ), .VIDEO_B ( core_b ), .VIDEO_EN ( core_de ), .AUDIO_L ( AUDIO_L ), .AUDIO_R ( AUDIO_R ), .I2C_DOUT ( i2c_din ), .I2C_DIN ( i2c_dout ), .I2C_CLOCK ( i2c_clock ), .fdd_led ( fdd_led ), .hdd_led ( hdd_led ), .sd_lba ( sd_lba ), .sd_rd ( sd_rd ), .sd_wr ( sd_wr ), .sd_ack ( |sd_ack ), .sd_buff_addr ( sd_buff_addr ), .sd_buff_dout ( sd_buff_dout ), .sd_buff_din ( sd_buff_din ), .sd_buff_wr ( sd_buff_wr ), .img_mounted ( img_mounted ), .img_size ( img_size ), .img_wp ( img_readonly ), .ide_req ( ide_req ), .ide_address ( ide_address ), .ide_write ( ide_write ), .ide_writedata ( ide_writedata ), .ide_read ( ide_read ), .ide_readdata ( ide_readdata ), .KBD_OUT_DATA ( kbd_out_data ), .KBD_OUT_STROBE ( kbd_out_strobe ), .KBD_IN_DATA ( kbd_in_data ), .KBD_IN_STROBE ( kbd_in_strobe ), .JOYSTICK0 (~{joyA[4],joyA[0],joyA[1],joyA[2],joyA[3]}), .JOYSTICK1 (~{joyB[4],joyB[0],joyB[1],joyB[2],joyB[3]}), .VIDBASECLK_O ( pixbaseclk_select ), .VIDSYNCPOL_O ( ) ); wire [31:0] vratio[16] = '{ 8000000, 12000000, 16000000, 24000000, 8391666, 12587500, 16783333, 25175000, 1200000, 18000000, 24000000, 36000000, 8000000, 12000000, 16000000, 24000000 }; wire [3:0] vmode = {pixbaseclk_select,selpix}; localparam CLKSYS = 42000000; reg cepix; reg [31:0] vclk, vsum; wire [31:0] vsum_next = vsum + vclk; always @(posedge CLK_VIDEO) begin cepix <= 0; vsum <= vsum_next; if(vsum_next >= CLKSYS) begin vsum <= vsum_next - CLKSYS; cepix <= 1; end end always @(posedge CLK_VIDEO) begin reg [31:0] pixcnt = 0, pix60; reg old_sync = 0; reg [31:0] vclk1; reg allow60 = 0; if(vmode == 7) allow60 <= 1; if(reset) allow60 <= 0; if(reset || status[4] || !allow60) vclk1 <= vratio[vmode]; else if(CE_PIXEL) begin old_sync <= VGA_VS; pixcnt <= pixcnt + 1; if(~old_sync & VGA_VS) begin pix60 <= {pixcnt[26:0],5'd0}+{pixcnt[27:0],4'd0}+{pixcnt[28:0],3'd0}+{pixcnt[29:0],2'd0}; pixcnt <= 0; end if(pix60<5000000) vclk1 <= 5000000; else if(pix60>CLKSYS) vclk1 <= CLKSYS; else vclk1 <= pix60; end vclk <= vclk1; end assign CLK_VIDEO = clk_sys; assign CE_PIXEL = cepix; assign VGA_F1 = 0; assign VGA_SL = 0; assign VGA_SCALER = 1; gamma_fast gamma ( .clk_vid(CLK_VIDEO), .ce_pix(CE_PIXEL), .gamma_bus(gamma_bus), .HSync(~core_hs), .VSync(~core_vs), .DE(core_de), .RGB_in({core_r,core_r,core_g,core_g,core_b,core_b}), .HSync_out(VGA_HS), .VSync_out(VGA_VS), .DE_out(vga_de), .RGB_out({VGA_R,VGA_G,VGA_B}) ); reg new_vmode; always @(posedge CLK_VIDEO) begin reg [4:0] old_mode; old_mode <= {status[4], vmode}; if(old_mode != {status[4], vmode}) new_vmode <= ~new_vmode; end wire [31:0] aratio[4] = '{ 1000000, 1048958, 1500000, 1000000 }; reg ceaud; reg [31:0] asum, aclk; wire [31:0] asum_next = asum + aclk; always @(posedge CLK_VIDEO) begin reg [31:0] aclk1; aclk1 <= (status[5] && pixbaseclk_select == 1) ? 1000000 : aratio[pixbaseclk_select]; aclk <= aclk1; ceaud <= 0; asum <= asum_next; if(asum_next >= CLKSYS) begin asum <= asum_next - CLKSYS; ceaud <= 1; end end wire ram_ack; wire ram_stb; wire ram_cyc; wire ram_we; wire [3:0] ram_sel; wire [25:2] ram_address; wire ram_ready; sdram SDRAM ( // wishbone interface .wb_clk (clk_sys ), .wb_stb (ram_stb ), .wb_cyc (ram_cyc ), .wb_we (ram_we ), .wb_ack (ram_ack ), .wb_sel (ram_sel ), .wb_adr (ram_address ), .wb_dat_i (ram_data_in ), .wb_dat_o (core_data_in), .wb_cti (core_cti_o ), // SDRAM Interface .sd_clk (clk_mem ), .sd_rst (~pll_ready ), .sd_clk_out (SDRAM_CLK ), .sd_cke (SDRAM_CKE ), .sd_dq (SDRAM_DQ ), .sd_addr (SDRAM_A ), .sd_dqm ({SDRAM_DQMH,SDRAM_DQML}), .sd_cs_n (SDRAM_nCS ), .sd_ba (SDRAM_BA ), .sd_we_n (SDRAM_nWE ), .sd_ras_n (SDRAM_nRAS ), .sd_cas_n (SDRAM_nCAS ), .sd_ready (ram_ready ) ); wire riscos_dl = (ioctl_index == 1) && ioctl_download; wire cmos_dl = (ioctl_index == 3) && ioctl_download; reg [21:2] erase_addr; reg loader_stb = 0; always @(posedge clk_sys) begin reg old_dl = 0; if(ram_ack) loader_stb <= 0; if(riscos_dl & ioctl_wr) loader_stb <= 1; old_dl <= riscos_dl; if(~old_dl & riscos_dl) begin ioctl_wait <= 1; erase_addr <= 0; end if(ioctl_wait) begin if(ram_ack) begin if(~&erase_addr) erase_addr <= erase_addr + 1'd1; else ioctl_wait <= 0; end if(~loader_stb) loader_stb <= 1; end end assign ram_we = riscos_dl ? 1'b1 : core_we_o; assign ram_sel = riscos_dl ? (ioctl_wait ? 4'b1111 : ioctl_addr[1] ? 4'b1100 : 4'b0011) : core_sel_o; assign ram_address = riscos_dl ? (ioctl_wait ? erase_addr : {2'b01,ioctl_addr[21:2]}) : core_address_out; assign ram_stb = riscos_dl ? loader_stb : core_stb_out; assign ram_cyc = riscos_dl ? loader_stb : core_cyc_out; assign ram_data_in = riscos_dl ? (ioctl_wait ? 32'd0 : {ioctl_dout,ioctl_dout}) : core_data_out; assign core_ack_in = riscos_dl ? 1'b0 : ram_ack; ////////////////// RTC/CMOS /////////////////// EEPROM_24C0x eeprom ( .clk(clk_sys), .ce(eep_ce), .reset(reset), .SCL(i2c_clock), .SDA_in(i2c_din), .SDA_out(i2c_dout), .type_24C01(0), .E_id(0), .WC_n(0), .data_from_ram(eep_dout), .data_to_ram(eep_din), .ram_addr(eep_addr), .ram_read(eep_read), .ram_write(eep_write), .ram_done(1) ); wire [7:0] eep_din; wire [7:0] eep_dout; wire [7:0] eep_addr; wire eep_read; wire eep_write; reg eep_ce; always @(posedge clk_sys) begin reg [1:0] cnt; cnt <= cnt + 1'd1; eep_ce <= !cnt; end reg [7:0] cmos_cnt = 0; always @(posedge clk_sys) if(eep_ce && eep_write && eep_addr >= 16) cmos_cnt <= cmos_cnt + 1'd1; dpram_dif #(8,8,7,16,"rtl/cmos.mif") memory ( .clock (clk_sys), .address_a (eep_addr), .data_a (eep_din), .wren_a (eep_write), .q_a (eep_dout), .address_b (ioctl_addr[7:1]), .data_b (ioctl_dout), .wren_b (ioctl_wr & cmos_dl), .q_b (ioctl_din) ); endmodule