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//
// Copyright 2013 Ettus Research LLC
//
/***********************************************************
* B200 Module Declaration
**********************************************************/
module b200 (
// SPI Interfaces
output cat_ce,
input cat_miso,
output cat_mosi,
output cat_sclk,
input fx3_ce,
output fx3_miso,
input fx3_mosi,
input fx3_sclk,
output pll_ce,
output pll_mosi,
output pll_sclk,
// UART
input FPGA_RXD0,
input FPGA_TXD0,
// Catalina Controls
output codec_enable,
output codec_en_agc,
output codec_reset,
output codec_sync,
output codec_txrx,
output [3:0] codec_ctrl_in, // These should be outputs
input [7:0] codec_ctrl_out, // MUST BE INPUT
// Catalina Data
input codec_data_clk_p, // Clock from CAT (RX)
output codec_fb_clk_p, // Clock to CAT (TX)
input [11:0] rx_codec_d,
output [11:0] tx_codec_d,
input rx_frame_p,
output tx_frame_p,
input cat_clkout_fpga,
//always on 40MHz clock
input codec_main_clk_p,
input codec_main_clk_n,
// Debug Bus
output [31:0] debug,
output [1:0] debug_clk,
// GPIF, FX3 Slave FIFO
output IFCLK, // pclk
input FX3_EXTINT,
output GPIF_CTL0, // n_slcs
output GPIF_CTL1, // n_slwr
output GPIF_CTL2, // n_sloe
output GPIF_CTL3, // n_slrd
output GPIF_CTL7, // n_pktend
input GPIF_CTL4, // slfifo_flags[0]
input GPIF_CTL5, // slfifo_flags[1]
input GPIF_CTL6, // slfifo_flags[2]
input GPIF_CTL8, // slfifo_flags[3]
output GPIF_CTL11, // slfifo_addr[1]
output GPIF_CTL12, // slfifo_addr[0]
inout [31:0] GPIF_D,
input GPIF_CTL9, // global_reset
// GPS
input gps_lock,
output gps_rxd,
input gps_txd,
input gps_txd_nmea,
// LEDS
output LED_RX1,
output LED_RX2,
output LED_TXRX1_RX,
output LED_TXRX1_TX,
output LED_TXRX2_RX,
output LED_TXRX2_TX,
// Misc Hardware Control
output ref_sel,
input pll_lock,
input FPGA_CFG_CS, // Driven by FX3 gpio.
input AUX_PWR_ON, // Driven by FX3 gpio.
// PPS
input PPS_IN_EXT,
input PPS_IN_INT,
// RF Hardware Control
output SFDX1_RX,
output SFDX1_TX,
output SFDX2_RX,
output SFDX2_TX,
output SRX1_RX,
output SRX1_TX,
output SRX2_RX,
output SRX2_TX,
output tx_bandsel_a,
output tx_bandsel_b,
output tx_enable1,
output tx_enable2,
output rx_bandsel_a,
output rx_bandsel_b,
output rx_bandsel_c
);
wire reset_global = GPIF_CTL9;
///////////////////////////////////////////////////////////////////////
// generate clocks from always on codec main clk
///////////////////////////////////////////////////////////////////////
wire bus_clk, gpif_clk, radio_clk;
wire locked;
b200_clk_gen gen_clks
(
.CLK_IN1_40_P(codec_main_clk_p), .CLK_IN1_40_N(codec_main_clk_n),
.CLK_OUT1_40_int(), .CLK_OUT2_100_gpif(gpif_clk), .CLK_OUT3_100_bus(bus_clk),
.RESET(reset_global), .LOCKED(locked)
);
//hold-off logic for clocks ready
reg [15:0] clocks_ready_count;
reg clocks_ready;
always @(posedge bus_clk or posedge reset_global or negedge locked) begin
if (reset_global | !locked) begin
clocks_ready_count <= 16'b0;
clocks_ready <= 1'b0;
end
else if (!clocks_ready) begin
clocks_ready_count <= clocks_ready_count + 1'b1;
clocks_ready <= (clocks_ready_count == 16'hffff);
end
end
///////////////////////////////////////////////////////////////////////
// drive output clocks
///////////////////////////////////////////////////////////////////////
wire [1:0] debug_clk_int;
//S6CLK2PIN S6CLK2PIN_dbg0 (.I(debug_clk_int[0]), .O(debug_clk[0]));
//S6CLK2PIN S6CLK2PIN_dbg1 (.I(debug_clk_int[1]), .O(debug_clk[1]));
assign debug_clk[1:0] = 2'b0;
S6CLK2PIN S6CLK2PIN_gpif (.I(gpif_clk), .O(IFCLK));
///////////////////////////////////////////////////////////////////////
// Create sync reset signals
///////////////////////////////////////////////////////////////////////
wire gpif_rst, bus_rst, radio_rst;
reset_sync gpif_sync(.clk(gpif_clk), .reset_in(!clocks_ready), .reset_out(gpif_rst));
reset_sync bus_sync(.clk(bus_clk), .reset_in(!clocks_ready), .reset_out(bus_rst));
reset_sync radio_sync(.clk(radio_clk), .reset_in(!clocks_ready), .reset_out(radio_rst));
///////////////////////////////////////////////////////////////////////
// CODEC capture/gen
///////////////////////////////////////////////////////////////////////
wire [31:0] rx_data1, rx_data2;
wire [31:0] tx_data1, tx_data2;
wire mimo, codec_arst;
catcodec_ddr_cmos catcodec
(
.radio_clk(radio_clk), .arst(codec_arst), .mimo(mimo),
.rx1(rx_data1), .rx2(rx_data2), .tx1(tx_data1), .tx2(tx_data2),
.rx_clk(codec_data_clk_p), .rx_frame(rx_frame_p), .rx_d(rx_codec_d),
.tx_clk(codec_fb_clk_p), .tx_frame(tx_frame_p), .tx_d(tx_codec_d)
);
///////////////////////////////////////////////////////////////////////
// SPI connections
///////////////////////////////////////////////////////////////////////
wire mosi, miso, sclk; wire [7:0] sen;
assign cat_ce = sen[0] & fx3_ce;
assign cat_mosi = (~sen[0] & mosi) | (~fx3_ce & fx3_mosi);
assign cat_sclk = (~sen[0] & sclk) | (~fx3_ce & fx3_sclk);
assign miso = cat_miso;
assign fx3_miso = ~fx3_ce & cat_miso;
assign pll_ce = sen[1];
assign pll_mosi = ~sen[1] & mosi;
assign pll_sclk = ~sen[1] & sclk;
///////////////////////////////////////////////////////////////////////
// bus signals
///////////////////////////////////////////////////////////////////////
wire [63:0] ctrl_tdata, resp_tdata, rx_tdata, tx_tdata;
wire ctrl_tlast, resp_tlast, rx_tlast, tx_tlast;
wire ctrl_tvalid, resp_tvalid, rx_tvalid, tx_tvalid;
wire ctrl_tready, resp_tready, rx_tready, tx_tready;
///////////////////////////////////////////////////////////////////////
// loopback testers
///////////////////////////////////////////////////////////////////////
/*
axi_fifo #(.WIDTH(65), .SIZE(13)) f0
(
.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
.i_tdata({ctrl_tlast, ctrl_tdata}), .i_tvalid(ctrl_tvalid), .i_tready(ctrl_tready), .space(),
.o_tdata({resp_tlast, resp_tdata}), .o_tvalid(resp_tvalid), .o_tready(resp_tready), .occupied()
);
//*/
/*
axi_fifo #(.WIDTH(65), .SIZE(13)) f1
(
.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
.i_tdata({tx_tlast, tx_tdata}), .i_tvalid(tx_tvalid), .i_tready(tx_tready), .space(),
.o_tdata({rx_tlast, rx_tdata}), .o_tvalid(rx_tvalid), .o_tready(rx_tready), .occupied()
);
//*/
///////////////////////////////////////////////////////////////////////
// frontend assignments
///////////////////////////////////////////////////////////////////////
wire [31:0] debug_radio;
wire [31:0] fe_atr1, fe_atr2;
assign {tx_enable1, SFDX1_RX, SFDX1_TX, SRX1_RX, SRX1_TX, LED_RX1, LED_TXRX1_RX, LED_TXRX1_TX} = fe_atr1[7:0];
assign {tx_enable2, SFDX2_RX, SFDX2_TX, SRX2_RX, SRX2_TX, LED_RX2, LED_TXRX2_RX, LED_TXRX2_TX} = fe_atr2[7:0];
wire [31:0] misc_outs; reg [31:0] misc_outs_r;
always @(posedge bus_clk) misc_outs_r <= misc_outs; //register misc ios to ease routing to flop
assign { tx_bandsel_a, tx_bandsel_b, rx_bandsel_a, rx_bandsel_b, rx_bandsel_c, codec_arst, mimo, ref_sel } = misc_outs_r[7:0];
assign codec_ctrl_in = 4'b1;
assign codec_en_agc = 1'b1;
assign codec_txrx = 1'b1;
assign codec_enable = 1'b1;
assign codec_reset = !reset_global; // Codec Reset // RESETB // Operates active-low
assign codec_sync = 1'b0;
///////////////////////////////////////////////////////////////////////
// b200 core
///////////////////////////////////////////////////////////////////////
b200_core #(.EXTRA_BUFF_SIZE(12)) b200_xfusion_core
(
.bus_clk(bus_clk), .bus_rst(bus_rst),
.tx_tdata(tx_tdata), .tx_tlast(tx_tlast), .tx_tvalid(tx_tvalid), .tx_tready(tx_tready),
.rx_tdata(rx_tdata), .rx_tlast(rx_tlast), .rx_tvalid(rx_tvalid), .rx_tready(rx_tready),
.ctrl_tdata(ctrl_tdata), .ctrl_tlast(ctrl_tlast), .ctrl_tvalid(ctrl_tvalid), .ctrl_tready(ctrl_tready),
.resp_tdata(resp_tdata), .resp_tlast(resp_tlast), .resp_tvalid(resp_tvalid), .resp_tready(resp_tready),
.radio_clk(radio_clk), .radio_rst(radio_rst),
.rx0(rx_data2), .rx1(rx_data1),
.tx0(tx_data2), .tx1(tx_data1),
.fe_atr0(fe_atr2), .fe_atr1(fe_atr1),
.pps_int(PPS_IN_INT), .pps_ext(PPS_IN_EXT),
.rxd(gps_txd), .txd(gps_rxd),
.sclk(sclk), .sen(sen), .mosi(mosi), .miso(miso),
.rb_misc({31'b0, pll_lock}), .misc_outs(misc_outs)
);
///////////////////////////////////////////////////////////////////////
// GPIF2
///////////////////////////////////////////////////////////////////////
wire [31:0] debug_gpif;
gpif2_slave_fifo32 #(.DATA_RX_FIFO_SIZE(14), .DATA_TX_FIFO_SIZE(14)) slave_fifo32
(
.gpif_clk(gpif_clk), .gpif_rst(gpif_rst), .gpif_enb(1'b1),
.gpif_ctl({GPIF_CTL8, GPIF_CTL6, GPIF_CTL5, GPIF_CTL4}), .fifoadr({GPIF_CTL11,GPIF_CTL12}),
.slwr(GPIF_CTL1), .sloe(GPIF_CTL2), .slcs(GPIF_CTL0), .slrd(GPIF_CTL3), .pktend(GPIF_CTL7),
.gpif_d(GPIF_D),
.fifo_clk(bus_clk), .fifo_rst(bus_rst),
.tx_tdata(tx_tdata), .tx_tlast(tx_tlast), .tx_tvalid(tx_tvalid), .tx_tready(tx_tready),
.rx_tdata(rx_tdata), .rx_tlast(rx_tlast), .rx_tvalid(rx_tvalid), .rx_tready(rx_tready),
.ctrl_tdata(ctrl_tdata), .ctrl_tlast(ctrl_tlast), .ctrl_tvalid(ctrl_tvalid), .ctrl_tready(ctrl_tready),
.resp_tdata(resp_tdata), .resp_tlast(resp_tlast), .resp_tvalid(resp_tvalid), .resp_tready(resp_tready),
.debug(debug_gpif)
);
///////////////////////////////////////////////////////////////////////
// Debug port
///////////////////////////////////////////////////////////////////////
assign debug_clk_int = { 1'b0, 1'b0 };
assign debug = 32'b0;
endmodule // B200
|