module Paella ( input wire CLK_50MHz, output wire LED, inout wire [3:0] TRG, inout wire [6:0] CON_A, inout wire [15:0] CON_B, inout wire [12:0] CON_C, input wire [1:0] CON_BCLK, input wire [1:0] CON_CCLK, input wire ADC_DCO, input wire ADC_FCO, input wire [2:0] ADC_D, output wire USB_SLRD, output wire USB_SLWR, input wire USB_IFCLK, input wire USB_FLAGA, // EMPTY flag for EP6 input wire USB_FLAGB, // FULL flag for EP8 input wire USB_FLAGC, inout wire USB_PA0, inout wire USB_PA1, output wire USB_PA2, inout wire USB_PA3, output wire USB_PA4, output wire USB_PA5, output wire USB_PA6, inout wire USB_PA7, inout wire [7:0] USB_PB, output wire RAM_CLK, output wire RAM_CE1, output wire RAM_WE, output wire [19:0] RAM_ADDR, inout wire RAM_DQAP, inout wire [7:0] RAM_DQA, inout wire RAM_DQBP, inout wire [7:0] RAM_DQB ); // Turn output ports off assign RAM_CLK = 1'b0; assign RAM_CE1 = 1'b0; assign RAM_WE = 1'b0; assign RAM_ADDR = 20'h00000; // Turn inout ports to tri-state assign TRG = 4'bz; assign CON_A = 7'bz; assign CON_B = 16'bz; assign CON_C = 13'bz; assign USB_PA0 = 1'bz; assign USB_PA1 = 1'bz; assign USB_PA3 = 1'bz; assign USB_PA7 = 1'bz; assign RAM_DQAP = 1'bz; assign RAM_DQA = 8'bz; assign RAM_DQBP = 1'bz; assign RAM_DQB = 8'bz; assign USB_PA2 = ~usb_rden; assign USB_PA4 = usb_addr[0]; assign USB_PA5 = usb_addr[1]; assign USB_PA6 = ~usb_pktend; wire usb_wrreq, usb_rdreq, usb_rden, usb_pktend; wire usb_aclr; wire usb_tx_wrreq, usb_rx_rdreq; wire usb_tx_full, usb_rx_empty; wire [7:0] usb_tx_data, usb_rx_data; wire [1:0] usb_addr; assign USB_SLRD = ~usb_rdreq; assign USB_SLWR = ~usb_wrreq; usb_fifo usb_unit ( .usb_clk(USB_IFCLK), .usb_data(USB_PB), .usb_full(~USB_FLAGB), .usb_empty(~USB_FLAGA), .usb_wrreq(usb_wrreq), .usb_rdreq(usb_rdreq), .usb_rden(usb_rden), .usb_pktend(usb_pktend), .usb_addr(usb_addr), .clk(CLK_50MHz), .aclr(usb_aclr), .tx_full(usb_tx_full), .tx_wrreq(usb_tx_wrreq), .tx_data(usb_tx_data), .rx_empty(usb_rx_empty), .rx_rdreq(usb_rx_rdreq), .rx_q(usb_rx_data) ); reg ana_reset [3:0]; wire ana_peak_ready [3:0]; wire [11:0] ana_peak [3:0]; reg osc_reset [3:0]; reg [9:0] osc_addr [3:0]; wire [9:0] osc_start_addr [3:0]; wire [15:0] osc_q [3:0]; reg hst_reset [3:0]; reg [11:0] hst_addr [3:0]; wire [23:0] hst_q [3:0]; wire mux_reset, mux_type; wire [1:0] mux_chan, mux_byte; wire [15:0] mux_addr; reg [7:0] mux_q; reg [1:0] mux_max_byte; reg [15:0] mux_min_addr, mux_max_addr; wire adc_clk [3:0]; wire adc_data_ready [3:0]; wire [11:0] adc_data [3:0]; wire [11:0] raw_data [3:0]; wire [11:0] uwt_data [3:0]; wire [1:0] uwt_flag [3:0]; assign adc_clk[0] = ADC_FCO; assign adc_clk[1] = ADC_FCO; assign adc_clk[2] = ADC_FCO; assign adc_clk[3] = CON_B[0]; assign adc_data[3] = CON_B[12:1]; /* wire adc_pll_clk; adc_pll adc_pll_unit( .inclk0(ADC_FCO), .c0(adc_pll_clk)); */ /* wire tst_adc_clk; wire [11:0] tst_adc_data; test test_unit( .inclk0(CLK_50MHz), .tst_clk(tst_adc_clk), .tst_data(tst_adc_data)); assign adc_clk[3] = tst_adc_clk; assign adc_data[3] = tst_adc_data; */ /* altserial_flash_loader #( .enable_shared_access("OFF"), .enhanced_mode(1), .intended_device_family("Cyclone III")) sfl_unit ( .noe(1'b0), .asmi_access_granted(), .asmi_access_request(), .data0out(), .dclkin(), .scein(), .sdoin()); */ adc_lvds adc_lvds_unit ( .lvds_dco(ADC_DCO), // .lvds_dco(adc_pll_clk), .lvds_fco(ADC_FCO), .lvds_d(ADC_D), .adc_db(adc_data[2]), .adc_dc(adc_data[1]), .adc_dd(adc_data[0])); genvar i; generate for (i = 2; i < 4; i = i + 1) begin : MCA_CHAIN adc_fifo adc_fifo_unit ( .adc_clk(adc_clk[i]), .adc_data(adc_data[i]), .clk(CLK_50MHz), .ready(adc_data_ready[i]), .raw_data(raw_data[i]), .uwt_data({uwt_flag[i], uwt_data[i]})); analyser analyser_unit ( .clk(CLK_50MHz), .reset(ana_reset[i]), .data_ready(adc_data_ready[i]), .uwt_flag(uwt_flag[i]), .uwt_data(uwt_data[i]), .threshold(12'd10), .peak_ready(ana_peak_ready[i]), .peak(ana_peak[i])); histogram histogram_unit ( .clk(CLK_50MHz), .reset(hst_reset[i]), .data_ready(adc_data_ready[i]), // .data(raw_data[i]), .data(uwt_data[i]), .address(hst_addr[i]), .q(hst_q[i])); /* histogram histogram_unit ( .clk(CLK_50MHz), .reset(hst_reset[i]), .data_ready(ana_peak_ready[i]), .data(ana_peak[i]), .address(hst_addr[i]), .q(hst_q[i])); */ oscilloscope oscilloscope_unit ( .clk(CLK_50MHz), .reset(osc_reset[i]), .data_ready(adc_data_ready[i]), .raw_data(raw_data[i]), .uwt_data(uwt_data[i]), .threshold(16'd40), .address(osc_addr[i]), .start_address(osc_start_addr[i]), .q(osc_q[i])); end endgenerate integer j; always @* begin for (j = 0; j < 4; j = j + 1) begin osc_reset[j] = 1'b0; osc_addr[j] = 10'b0; hst_reset[j] = 1'b0; hst_addr[j] = 12'b0; end case({mux_type, mux_chan}) 3'b000, 3'b001, 3'b010, 3'b011: begin osc_reset[mux_chan] = mux_reset; osc_addr[mux_chan] = mux_addr[9:0]; mux_max_byte = 2'd1; mux_min_addr = {6'd0, osc_start_addr[mux_chan]}; mux_max_addr = 16'd1023; end 3'b100, 3'b101, 3'b110, 3'b111: begin hst_reset[mux_chan] = mux_reset; hst_addr[mux_chan] = mux_addr[11:0]; mux_max_byte = 2'd2; mux_min_addr = 16'd0; mux_max_addr = 16'd4095; end endcase end always @* begin case ({mux_type, mux_byte}) 3'b000: mux_q = osc_q[mux_chan][7:0]; 3'b001: mux_q = osc_q[mux_chan][15:8]; 3'b100: mux_q = hst_q[mux_chan][7:0]; 3'b101: mux_q = hst_q[mux_chan][15:8]; 3'b110: mux_q = hst_q[mux_chan][23:16]; default: mux_q = 8'd0; endcase end control control_unit ( .clk(CLK_50MHz), .rx_empty(usb_rx_empty), .tx_full(usb_tx_full), .rx_data(usb_rx_data), .mux_max_byte(mux_max_byte), .mux_min_addr(mux_min_addr), .mux_max_addr(mux_max_addr), .mux_q(mux_q), .mux_reset(mux_reset), .mux_type(mux_type), .mux_chan(mux_chan), .mux_byte(mux_byte), .mux_addr(mux_addr), .rx_rdreq(usb_rx_rdreq), .tx_wrreq(usb_tx_wrreq), .tx_data(usb_tx_data), .led(LED)); endmodule