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//
// Copyright 2011-2012 Ettus Research LLC
//
// 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 3 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, see <http://www.gnu.org/licenses/>.
//
module u1plus_core
#(
parameter NUM_RX_DSPS = 2,
parameter CTRL_ACK_SID = 20, //needed for reply
parameter DSP_TX_FIFOSIZE = 10, //4K MTU
parameter DSP_RX_FIFOSIZE = 10, //4K MTU
parameter DSP_RX_XTRA_FIFOSIZE = 11,
parameter DSP_TX_XTRA_FIFOSIZE = 11,
parameter USE_PACKET_PADDER = 0
)
(input clk, input reset,
output [31:0] debug, output [1:0] debug_clk,
// Host Interface
input [35:0] tx_data, input tx_src_rdy, output tx_dst_rdy,
output [35:0] rx_data, output rx_src_rdy, input rx_dst_rdy,
input [35:0] ctrl_data, input ctrl_src_rdy, output ctrl_dst_rdy,
output [35:0] resp_data, output resp_src_rdy, input resp_dst_rdy,
output dsp_rx_run, output dsp_tx_run, output clock_sync,
inout db_sda, inout db_scl,
output sclk, output [7:0] sen, output mosi, input miso,
inout [15:0] io_tx, inout [15:0] io_rx,
output [13:0] tx_i, output [13:0] tx_q,
input [11:0] rx_i, input [11:0] rx_q,
input pps_in
);
localparam SR_MISC = 0; // 5
localparam SR_USER_REGS = 5; // 2
localparam SR_PADDER = 10; // 2
localparam SR_TX_CTRL = 32; // 6
localparam SR_TX_DSP = 40; // 5
localparam SR_TX_FE = 48; // 5
localparam SR_RX_CTRL0 = 96; // 9
localparam SR_RX_DSP0 = 106; // 7
localparam SR_RX_FE = 114; // 5
localparam SR_RX_CTRL1 = 128; // 9
localparam SR_RX_DSP1 = 138; // 7
localparam SR_TIME64 = 192; // 6
localparam SR_SPI = 208; // 3
localparam SR_I2C = 216; // 1
localparam SR_GPIO = 224; // 5
//compatibility number -> increment when the fpga has been sufficiently altered
localparam compat_num = {16'd11, 16'd1}; //major, minor
//assign run signals used for ATR logic
wire [NUM_RX_DSPS-1:0] run_rx_n;
wire run_tx;
wire run_rx = |(run_rx_n);
assign dsp_rx_run = run_rx;
assign dsp_tx_run = run_tx;
//shared time core signals
wire [63:0] vita_time, vita_time_pps;
//shared settings bus signals
wire set_stb, set_stb_user;
wire [31:0] set_data, set_data_user;
wire [7:0] set_addr, set_addr_user;
//shared SPI core signals
wire [31:0] spi_readback;
wire spi_ready;
//shared I2C core signals
wire [31:0] i2c_readback;
wire i2c_ready;
//shared GPIO core signals
wire [31:0] gpio_readback;
///////////////////////////////////////////////////////////////////////////
// Misc Registers - persistent across resets
///////////////////////////////////////////////////////////////////////////
wire [31:0] config_word0;
setting_reg #(.my_addr(SR_MISC+0), .width(32)) sr_misc_config0
(.clk(clk), .rst(1'b0/*reset*/), .strobe(set_stb), .addr(set_addr), .in(set_data), .out(config_word0));
wire [31:0] config_word1;
setting_reg #(.my_addr(SR_MISC+1), .width(32)) sr_misc_config1
(.clk(clk), .rst(1'b0/*reset*/), .strobe(set_stb), .addr(set_addr), .in(set_data), .out(config_word1));
wire clock_sync_inv, clock_sync_enb;
setting_reg #(.my_addr(SR_MISC+2), .width(2)) sr_misc_clock_sync
(.clk(clk), .rst(reset), .strobe(set_stb), .addr(set_addr), .in(set_data),
.out({clock_sync_inv, clock_sync_enb}));
///////////////////////////////////////////////////////////////////////////
// Settings Bus and Readback
///////////////////////////////////////////////////////////////////////////
user_settings #(.BASE(SR_USER_REGS)) user_settings
(.clk(clk),.rst(reset),
.set_stb(set_stb), .set_addr(set_addr),.set_data(set_data),
.set_addr_user(set_addr_user),.set_data_user(set_data_user), .set_stb_user(set_stb_user) );
wire [35:0] ctrl_out_data, ctrl_int_data;
wire ctrl_out_src_rdy, ctrl_out_dst_rdy;
wire ctrl_int_src_rdy, ctrl_int_dst_rdy;
fifo_cascade #(.WIDTH(36), .SIZE(9)) ctrl_fifo
(.clk(clk), .reset(reset), .clear(1'b0),
.datain(ctrl_data), .src_rdy_i(ctrl_src_rdy), .dst_rdy_o(ctrl_dst_rdy), .space(),
.dataout(ctrl_int_data), .src_rdy_o(ctrl_int_src_rdy), .dst_rdy_i(ctrl_int_dst_rdy), .occupied());
wire [31:0] num_rx_dsps_rb = NUM_RX_DSPS;
wire [31:0] sfc_debug;
settings_fifo_ctrl #(.PROT_HDR(0), .ACK_SID(CTRL_ACK_SID), .XPORT_HDR(0)) sfc
(
.clock(clk), .reset(reset), .clear(1'b0),
.vita_time(vita_time), .perfs_ready(spi_ready & i2c_ready),
.in_data(ctrl_int_data), .in_valid(ctrl_int_src_rdy), .in_ready(ctrl_int_dst_rdy),
.out_data(ctrl_out_data), .out_valid(ctrl_out_src_rdy), .out_ready(ctrl_out_dst_rdy),
.strobe(set_stb), .addr(set_addr), .data(set_data),
.word00(spi_readback),.word01(compat_num),.word02(i2c_readback),.word03(gpio_readback),
.word04(config_word0),.word05(config_word1),.word06(num_rx_dsps_rb),.word07(32'hffff_ffff),
.word08(32'hffff_ffff),.word09(32'hffff_ffff),.word10(vita_time[63:32]),
.word11(vita_time[31:0]),.word12(32'hffff_ffff),.word13(32'hffff_ffff),
.word14(vita_time_pps[63:32]),.word15(vita_time_pps[31:0]),
.debug(sfc_debug)
);
///////////////////////////////////////////////////////////////////////////
// Time Core
///////////////////////////////////////////////////////////////////////////
time_64bit #(.BASE(SR_TIME64)) time_64bit
(.clk(clk), .rst(reset), .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.pps(pps_in), .vita_time(vita_time), .vita_time_pps(vita_time_pps),
.exp_time_in(0));
assign clock_sync = (clock_sync_enb)? (pps_in ^ clock_sync_inv) : 1'b0;
///////////////////////////////////////////////////////////////////////////
// SPI Core
///////////////////////////////////////////////////////////////////////////
simple_spi_core #(.BASE(SR_SPI), .WIDTH(8), .CLK_IDLE(0), .SEN_IDLE(8'hff))
simple_spi_core (.clock(clk), .reset(reset),
.set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.readback(spi_readback), .ready(spi_ready),
.sen(sen), .sclk(sclk), .mosi(mosi), .miso(miso));
///////////////////////////////////////////////////////////////////////////
// I2C Core
///////////////////////////////////////////////////////////////////////////
wire scl_pad_i, scl_pad_o, scl_pad_oen_o, sda_pad_i, sda_pad_o, sda_pad_oen_o;
simple_i2c_core #(.BASE(SR_I2C)) i2c_core
(.clock(clk),.reset(reset),
.set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.readback(i2c_readback), .ready(i2c_ready),
.scl_pad_i(scl_pad_i),.scl_pad_o(scl_pad_o),.scl_padoen_o(scl_pad_oen_o),
.sda_pad_i(sda_pad_i),.sda_pad_o(sda_pad_o),.sda_padoen_o(sda_pad_oen_o) );
// I2C -- Don't use external transistors for open drain, the FPGA implements this
IOBUF scl_pin(.O(scl_pad_i), .IO(db_scl), .I(scl_pad_o), .T(scl_pad_oen_o));
IOBUF sda_pin(.O(sda_pad_i), .IO(db_sda), .I(sda_pad_o), .T(sda_pad_oen_o));
///////////////////////////////////////////////////////////////////////////
// GPIO Core
///////////////////////////////////////////////////////////////////////////
gpio_atr #(.BASE(SR_GPIO), .WIDTH(32))
gpio_atr(.clk(clk),.reset(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.rx(run_rx), .tx(run_tx), .gpio({io_tx, io_rx}), .gpio_readback(gpio_readback) );
// /////////////////////////////////////////////////////////////////////////
// RX ADC Frontend, does IQ Balance, DC Offset, muxing
wire [23:0] rx_fe_i, rx_fe_q; // 24 bits is total overkill here, but it matches u2/u2p
rx_frontend #(.BASE(SR_RX_FE)) rx_frontend
(.clk(clk),.rst(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.adc_a({rx_i,4'b00}),.adc_ovf_a(0),
.adc_b({rx_q,4'b00}),.adc_ovf_b(0),
.i_out(rx_fe_i), .q_out(rx_fe_q), .run(run_rx), .debug());
// /////////////////////////////////////////////////////////////////////////
// DSP RX *
wire [35:0] rx_int2_data [NUM_RX_DSPS-1:0];
wire rx_int2_src_rdy [NUM_RX_DSPS-1:0];
wire rx_int2_dst_rdy [NUM_RX_DSPS-1:0];
genvar dspno;
generate
for(dspno = 0; dspno < NUM_RX_DSPS; dspno = dspno + 1) begin:gen_rx_dsps
wire [31:0] sample_rx;
wire strobe_rx, clear_rx;
wire [35:0] vita_rx_data;
wire vita_rx_src_rdy, vita_rx_dst_rdy;
wire [35:0] int_rx_data;
wire int_rx_src_rdy, int_rx_dst_rdy;
ddc_chain #(.BASE(SR_RX_DSP0+dspno*32), .DSPNO(dspno)) ddc_chain
(.clk(clk), .rst(reset), .clr(clear_rx),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user),
.rx_fe_i(rx_fe_i),.rx_fe_q(rx_fe_q),
.sample(sample_rx), .run(run_rx_n[dspno]), .strobe(strobe_rx),
.debug() );
vita_rx_chain #(.BASE(SR_RX_CTRL0+dspno*32), .UNIT(dspno), .FIFOSIZE(DSP_RX_FIFOSIZE), .PROT_ENG_FLAGS(0), .DSP_NUMBER(dspno)) vita_rx_chain
(.clk(clk),.reset(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user),
.vita_time(vita_time), .overrun(),
.sample(sample_rx), .run(run_rx_n[dspno]), .strobe(strobe_rx), .clear_o(clear_rx),
.rx_data_o(vita_rx_data), .rx_dst_rdy_i(vita_rx_dst_rdy), .rx_src_rdy_o(vita_rx_src_rdy),
.debug() );
fifo_cascade #(.WIDTH(36), .SIZE(DSP_RX_FIFOSIZE+1)) rx_data_fifo
(.clk(clk), .reset(reset), .clear(1'b0),
.datain(vita_rx_data), .src_rdy_i(vita_rx_src_rdy), .dst_rdy_o(vita_rx_dst_rdy), .space(),
.dataout(int_rx_data), .src_rdy_o(int_rx_src_rdy), .dst_rdy_i(int_rx_dst_rdy), .occupied());
if (dspno == 0) begin
assign rx_int2_data[dspno] = int_rx_data;
assign rx_int2_src_rdy[dspno] = int_rx_src_rdy;
assign int_rx_dst_rdy = rx_int2_dst_rdy[dspno];
end
else begin
fifo36_mux #(.prio(0)) // No priority, fair sharing
combine_rx_dsps (
.clk(clk), .reset(reset), .clear(1'b0/*noclear*/),
.data0_i(rx_int2_data[dspno-1]), .src0_rdy_i(rx_int2_src_rdy[dspno-1]), .dst0_rdy_o(rx_int2_dst_rdy[dspno-1]),
.data1_i(int_rx_data), .src1_rdy_i(int_rx_src_rdy), .dst1_rdy_o(int_rx_dst_rdy),
.data_o(rx_int2_data[dspno]), .src_rdy_o(rx_int2_src_rdy[dspno]), .dst_rdy_i(rx_int2_dst_rdy[dspno])
);
end
end
endgenerate
// /////////////////////////////////////////////////////////////////////////
// RX Stream muxing
wire [35:0] rx_int3_data;
wire rx_int3_src_rdy, rx_int3_dst_rdy;
fifo_cascade #(.WIDTH(36), .SIZE(DSP_RX_XTRA_FIFOSIZE)) rx_data_fifo_combined
(.clk(clk), .reset(reset), .clear(1'b0),
.datain(rx_int2_data[NUM_RX_DSPS-1]), .src_rdy_i(rx_int2_src_rdy[NUM_RX_DSPS-1]), .dst_rdy_o(rx_int2_dst_rdy[NUM_RX_DSPS-1]), .space(),
.dataout(rx_int3_data), .src_rdy_o(rx_int3_src_rdy), .dst_rdy_i(rx_int3_dst_rdy), .occupied());
generate
if (USE_PACKET_PADDER) begin
packet_padder36 #(.BASE(SR_PADDER)) packet_padder_rx_data36(
.clk(clk), .reset(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.data_i(rx_int3_data), .src_rdy_i(rx_int3_src_rdy), .dst_rdy_o(rx_int3_dst_rdy),
.data_o(rx_data), .src_rdy_o(rx_src_rdy), .dst_rdy_i(rx_dst_rdy),
.always_flush(~dsp_rx_run));
end
else begin
assign rx_data = rx_int3_data;
assign rx_src_rdy = rx_int3_src_rdy;
assign rx_int3_dst_rdy = rx_dst_rdy;
end
endgenerate
///////////////////////////////////////////////////////////////////////////
// MUX for TX async and resp data
///////////////////////////////////////////////////////////////////////////
wire [35:0] tx_err_data, resp_data_int;
wire tx_err_src_rdy, resp_src_rdy_int;
wire tx_err_dst_rdy, resp_dst_rdy_int;
fifo36_mux #(.prio(0)) // No priority, fair sharing
combine_async_and_resp (
.clk(clk), .reset(reset), .clear(1'b0/*noclear*/),
.data0_i(ctrl_out_data), .src0_rdy_i(ctrl_out_src_rdy), .dst0_rdy_o(ctrl_out_dst_rdy),
.data1_i(tx_err_data), .src1_rdy_i(tx_err_src_rdy), .dst1_rdy_o(tx_err_dst_rdy),
.data_o(resp_data_int), .src_rdy_o(resp_src_rdy_int), .dst_rdy_i(resp_dst_rdy_int)
);
fifo_cascade #(.WIDTH(36), .SIZE(9)) resp_fifo
(.clk(clk), .reset(reset), .clear(1'b0),
.datain(resp_data_int), .src_rdy_i(resp_src_rdy_int), .dst_rdy_o(resp_dst_rdy_int), .space(),
.dataout(resp_data), .src_rdy_o(resp_src_rdy), .dst_rdy_i(resp_dst_rdy), .occupied());
// ///////////////////////////////////////////////////////////////////////////////////
// DSP TX
wire [23:0] tx_fe_i, tx_fe_q;
wire [31:0] sample_tx;
wire strobe_tx, clear_tx;
`ifdef DISABLE_TX_DSP
assign tx_dst_rdy = 1; //null sink
assign run_tx = 0;
assign tx_i = 0;
assign tx_q = 0;
`else
vita_tx_chain #(.BASE(SR_TX_CTRL),
.FIFOSIZE(DSP_TX_FIFOSIZE),
.POST_ENGINE_FIFOSIZE(DSP_TX_XTRA_FIFOSIZE),
.REPORT_ERROR(1), .DO_FLOW_CONTROL(0),
.PROT_ENG_FLAGS(0), .USE_TRANS_HEADER(0),
.DSP_NUMBER(0))
vita_tx_chain
(.clk(clk), .reset(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user),
.vita_time(vita_time),
.tx_data_i(tx_data), .tx_src_rdy_i(tx_src_rdy), .tx_dst_rdy_o(tx_dst_rdy),
.err_data_o(tx_err_data), .err_src_rdy_o(tx_err_src_rdy), .err_dst_rdy_i(tx_err_dst_rdy),
.sample(sample_tx), .strobe(strobe_tx),
.underrun(), .run(run_tx), .clear_o(clear_tx),
.debug());
duc_chain #(.BASE(SR_TX_DSP), .DSPNO(0)) duc_chain
(.clk(clk), .rst(reset), .clr(clear_tx),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user),
.tx_fe_i(tx_fe_i),.tx_fe_q(tx_fe_q),
.sample(sample_tx), .run(run_tx), .strobe(strobe_tx),
.debug() );
tx_frontend #(.BASE(SR_TX_FE), .WIDTH_OUT(14)) tx_frontend
(.clk(clk), .rst(reset),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.tx_i(tx_fe_i), .tx_q(tx_fe_q), .run(1'b1),
.dac_a(tx_i), .dac_b(tx_q));
`endif
// /////////////////////////////////////////////////////////////////////////////////////
// Debug circuitry
assign debug_clk = 2'b11;
assign debug = 32'hffffffff;
endmodule // u1plus_core
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