module Paella ( input wire CLK_100MHz, output wire LED, input wire ADC_DCO, input wire ADC_FCO, input wire [5:0] 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 output wire USB_PA2, output wire USB_PA4, output wire USB_PA6, inout wire [7:0] USB_PB, output wire RAM_CLK, output wire RAM_WE, output wire [21:0] RAM_ADDR, inout wire RAM_DQAP, inout wire [7:0] RAM_DQA, inout wire RAM_DQBP, inout wire [7:0] RAM_DQB ); localparam N = 6; // Turn output ports off /* assign RAM_CLK = 1'b0; assign RAM_CE1 = 1'b0; assign RAM_WE = 1'b0; assign RAM_ADDR = 20'h00000; */ assign RAM_CLK = sys_clock; assign USB_PA2 = ~usb_rden; assign USB_PA4 = usb_addr; assign USB_PA6 = ~usb_pktend; wire usb_wrreq, usb_rdreq, usb_rden, usb_pktend; wire usb_tx_wrreq, usb_rx_rdreq; wire usb_tx_full, usb_rx_empty; wire [7:0] usb_tx_data, usb_rx_data; wire usb_addr; assign USB_SLRD = ~usb_rdreq; assign USB_SLWR = ~usb_wrreq; usb_fifo usb_unit ( .usb_clock(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), .clock(sys_clock), .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 [31:0] led_counter; always @(posedge CLK_50MHz) begin led_counter = led_counter + 32'd1; end assign LED = led_counter[28]; */ wire [11:0] osc_mux_data [4:0]; wire [11:0] trg_mux_data; wire trg_flag; wire [6*12-1:0] int_mux_data [N-1:0]; wire [1:0] amp_flag [3*N-1:0]; wire [12:0] amp_data [3*N-1:0]; wire cls_flag; wire [7:0] cls_data; wire [1:0] amp_mux_flag [2:0]; wire [11:0] amp_mux_data [2:0]; wire cnt_good [3:0]; wire [15:0] cnt_bits_wire; wire sys_clock, sys_frame; wire [11:0] adc_data [N-1:0]; wire [11:0] sys_data [N-1:0]; wire [11:0] tst_data; wire [3:0] cmp_data; wire [1:0] del_data; wire [19:0] cic_data [N-1:0]; wire [11:0] dec_data [N-1:0]; wire [12:0] clp_data [N-1:0]; wire [11:0] tmp_data; wire i2c_reset; assign tmp_data = 12'd0; /* assign sys_clock = CLK_100MHz; */ sys_pll sys_pll_unit( .inclk0(CLK_100MHz), .c0(sys_clock)); /* sys_pll sys_pll_unit( .inclk0(CLK_100MHz), .c0(sys_clock), .c1(ADC_DCO), .c2(ADC_FCO)); wire ADC_DCO, ADC_FCO; test test_unit( .clock(ADC_FCO), .data(tst_data)); */ adc_lvds #( .size(6), .width(12)) adc_lvds_unit ( .clock(sys_clock), .lvds_dco(ADC_DCO), .lvds_fco(ADC_FCO), .lvds_d(ADC_D), // .test(tst_data), .adc_frame(sys_frame), .adc_data({ adc_data[5], adc_data[3], adc_data[4], // D3, D1, D2 adc_data[2], adc_data[1], adc_data[0]})); // S2, S1_S, S1_F wire [15:0] cfg_bits [63:0]; wire [1023:0] int_cfg_bits; wire [39:0] cfg_mux_selector; wire cfg_reset; wire [2:0] bus_ssel; wire bus_wren; wire [31:0] bus_addr; wire [15:0] bus_mosi; wire [15:0] bus_miso [2:0]; wire [2:0] bus_busy; wire [15:0] mrg_bus_miso; wire mrg_bus_busy; wire [3*16-1:0] int_bus_miso; genvar j; generate for (j = 0; j < 64; j = j + 1) begin : CONFIGURATION_OUTPUT assign cfg_bits[j] = int_cfg_bits[j*16+15:j*16]; end endgenerate configuration configuration_unit ( .clock(sys_clock), .reset(cfg_reset), .bus_ssel(bus_ssel[0]), .bus_wren(bus_wren), .bus_addr(bus_addr[5:0]), .bus_mosi(bus_mosi), .bus_miso(bus_miso[0]), .bus_busy(bus_busy[0]), .cfg_bits(int_cfg_bits)); generate for (j = 0; j < 6; j = j + 1) begin : MUX_DATA assign int_mux_data[j] = { {4'd0, cls_flag, 7'd0}, {4'd0, cls_data}, {4'd0, amp_flag[j][0], 7'd0}, amp_data[j][11:0], clp_data[j][11:0], sys_data[j] }; end endgenerate assign cfg_mux_selector = {cfg_bits[4][7:0], cfg_bits[3], cfg_bits[2]}; lpm_mux #( .lpm_size(6*6), .lpm_type("LPM_MUX"), .lpm_width(12), .lpm_widths(6)) trg_mux_unit ( .sel(cfg_bits[4][13:8]), .data({ int_mux_data[5], int_mux_data[4], int_mux_data[3], int_mux_data[2], int_mux_data[1], int_mux_data[0]}), .result(trg_mux_data)); generate for (j = 0; j < 5; j = j + 1) begin : OSC_CHAIN lpm_mux #( .lpm_size(6*6), .lpm_type("LPM_MUX"), .lpm_width(12), .lpm_widths(6)) osc_mux_unit ( .sel(cfg_mux_selector[j*8+5:j*8]), .data({ int_mux_data[5], int_mux_data[4], int_mux_data[3], int_mux_data[2], int_mux_data[1], int_mux_data[0]}), .result(osc_mux_data[j])); end endgenerate trigger trigger_unit ( .clock(sys_clock), .frame(sys_frame), .reset(cfg_bits[0][0]), .cfg_data(cfg_bits[5][11:0]), .trg_data(trg_mux_data), .trg_flag(trg_flag)); oscilloscope oscilloscope_unit ( .clock(sys_clock), .frame(sys_frame), .reset(cfg_bits[0][1]), .cfg_data(cfg_bits[5][12]), .trg_flag(trg_flag), .osc_data({cmp_data[3:0], osc_mux_data[4], osc_mux_data[3], osc_mux_data[2], osc_mux_data[1], osc_mux_data[0]}), .ram_wren(RAM_WE), .ram_addr(RAM_ADDR), .ram_data({RAM_DQA, RAM_DQAP, RAM_DQB, RAM_DQBP}), .bus_ssel(bus_ssel[1]), .bus_wren(bus_wren), .bus_addr(bus_addr[19:0]), .bus_mosi(bus_mosi), .bus_miso(bus_miso[1]), .bus_busy(bus_busy[1])); filter #(.size(6), .width(12)) filter_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), .inp_data({sys_data[5], sys_data[4], sys_data[3], sys_data[2], sys_data[1], sys_data[0]}), .out_data({cic_data[5], cic_data[4], cic_data[3], cic_data[2], cic_data[1], cic_data[0]})); /* new_filter #(.size(6), .width(12)) filter_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), .inp_data({sys_data[5], sys_data[4], sys_data[3], sys_data[2], sys_data[1], sys_data[0]}), .out_data({cic_data[5], cic_data[4], cic_data[3], cic_data[2], cic_data[1], cic_data[0]})); */ generate for (j = 0; j < 2; j = j + 1) begin : DECONV_CHAIN clip #(.shift(21), .width(19), .widthr(13)) clip_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), // .del_data({6'd0, 6'd32, 6'd32, 6'd32}), .del_data({6'd0, cfg_bits[43+6*j][5:0], cfg_bits[41+6*j][5:0], cfg_bits[39+6*j][5:0]}), .amp_data({6'd0, 6'd20, 6'd20, 6'd20}), // .tau_data({16'd0, 16'd19835, 16'd19835, 16'd19835}), // exp(-32/1000)*1024*20 .tau_data({16'd0, cfg_bits[42+6*j], cfg_bits[40+6*j], cfg_bits[38+6*j]}), .inp_data({ 19'd0, cic_data[j*3+2][18:0], cic_data[j*3+1][18:0], cic_data[j*3+0][18:0]}), .out_data({ tmp_data, clp_data[j*3+2], clp_data[j*3+1], clp_data[j*3+0]})); end endgenerate generate for (j = 0; j < 6; j = j + 1) begin : MCA_CHAIN /* shift #(.shift(11), .width(19), .widthr(13)) shift_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), .amp_data(6'd21), .inp_data(cic_data[j][18:0]), .out_data(clp_data[j])); */ assign sys_data[j] = (cfg_bits[1][j]) ? (adc_data[j] ^ 12'hfff) : (adc_data[j]); amplitude #(.width(13)) amplitude_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), // .min_data(13'd20), .min_data(cfg_bits[10+j][12:0]), .max_data(13'd4095), .inp_data(clp_data[j]), .out_flag(amp_flag[j]), .out_data(amp_data[j])); end endgenerate // {D3, D2, D1, S2, S1_S, S1_F} classifier #(.width(12)) classifier_unit ( .clock(sys_clock), .frame(sys_frame), .reset(1'b0), // .cfg_data({12'd20, 12'd20, // 12'd20, 12'd20, 12'd20, 12'd20, 12'd2000, 12'd20, // 12'd20, 12'd2000, 12'd2000, 12'd20, 12'd1000, 12'd1000}), .cfg_data({cfg_bits[37][11:0], cfg_bits[36][11:0], cfg_bits[35][11:0], cfg_bits[34][11:0], cfg_bits[33][11:0], cfg_bits[32][11:0], cfg_bits[31][11:0], cfg_bits[30][11:0], cfg_bits[29][11:0], cfg_bits[28][11:0], cfg_bits[27][11:0], cfg_bits[26][11:0], cfg_bits[25][11:0], cfg_bits[24][11:0], cfg_bits[23][11:0], cfg_bits[22][11:0], cfg_bits[21][11:0], cfg_bits[20][11:0], cfg_bits[19][11:0], cfg_bits[18][11:0], cfg_bits[17][11:0], cfg_bits[16][11:0]}), .inp_data({amp_data[5][11:0], amp_data[4][11:0], amp_data[3][11:0], amp_data[2][11:0], amp_data[1][11:0], amp_data[0][11:0]}), .inp_flag({amp_flag[5][0], amp_flag[4][0], amp_flag[3][0], amp_flag[2][0], amp_flag[1][0], amp_flag[0][0]}), .out_flag(cls_flag), .out_data(cls_data)); histogram32 histogram32_unit ( .clock(sys_clock), .frame(sys_frame), .reset(cfg_bits[0][5]), .hst_good(cls_flag & cfg_bits[6][0]), .hst_data(cls_data[6:0]), .bus_ssel(bus_ssel[2]), .bus_wren(bus_wren), .bus_addr(bus_addr[7:0]), .bus_mosi(bus_mosi), .bus_miso(bus_miso[2]), .bus_busy(bus_busy[2])); generate for (j = 0; j < 3; j = j + 1) begin : BUS_OUTPUT assign int_bus_miso[j*16+15:j*16] = bus_miso[j]; end endgenerate lpm_mux #( .lpm_size(3), .lpm_type("LPM_MUX"), .lpm_width(16), .lpm_widths(2)) bus_miso_mux_unit ( .sel(bus_addr[29:28]), .data(int_bus_miso), .result(mrg_bus_miso)); lpm_mux #( .lpm_size(3), .lpm_type("LPM_MUX"), .lpm_width(1), .lpm_widths(2)) bus_busy_mux_unit ( .sel(bus_addr[29:28]), .data(bus_busy), .result(mrg_bus_busy)); lpm_decode #( .lpm_decodes(3), .lpm_type("LPM_DECODE"), .lpm_width(2)) lpm_decode_unit ( .data(bus_addr[29:28]), .eq(bus_ssel)); control control_unit ( .clock(sys_clock), .rx_empty(usb_rx_empty), .tx_full(usb_tx_full), .rx_data(usb_rx_data), .rx_rdreq(usb_rx_rdreq), .tx_wrreq(usb_tx_wrreq), .tx_data(usb_tx_data), .bus_wren(bus_wren), .bus_addr(bus_addr), .bus_mosi(bus_mosi), .bus_miso(mrg_bus_miso), .bus_busy(mrg_bus_busy), .led(LED)); /* 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()); */ endmodule