//
// 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/>.
//

//! The USRP digital down-conversion chain

module ddc_chain
  #(
    parameter BASE = 0,
    parameter DSPNO = 0,
    parameter WIDTH = 24
  )
  (input clk, input rst, input clr,
   input set_stb, input [7:0] set_addr, input [31:0] set_data,
   input set_stb_user, input [7:0] set_addr_user, input [31:0] set_data_user,

   // From RX frontend
   input [WIDTH-1:0] rx_fe_i,
   input [WIDTH-1:0] rx_fe_q,

   // To RX control
   output [31:0] sample,
   input run,
   output strobe,
   output [31:0] debug
   );

   localparam  cwidth = 25;
   localparam  zwidth = 24;

   wire ddc_enb;
   wire [31:0] phase_inc;
   reg [31:0]  phase;

   wire [17:0] scale_factor;
   wire [cwidth-1:0] i_cordic, q_cordic;
   wire [WIDTH-1:0] i_cordic_clip, q_cordic_clip;
   wire [WIDTH-1:0] i_cic, q_cic;
   wire [WIDTH-1:0] i_hb1, q_hb1;
   wire [WIDTH-1:0] i_hb2, q_hb2;
   
   wire        strobe_cic, strobe_hb1, strobe_hb2;
   wire        enable_hb1, enable_hb2;
   wire [7:0]  cic_decim_rate;

   reg [WIDTH-1:0]  rx_fe_i_mux, rx_fe_q_mux;
   wire        realmode;
   wire        swap_iq;
   
   setting_reg #(.my_addr(BASE+0)) sr_0
     (.clk(clk),.rst(rst),.strobe(set_stb),.addr(set_addr),
      .in(set_data),.out(phase_inc),.changed());

   setting_reg #(.my_addr(BASE+1), .width(18)) sr_1
     (.clk(clk),.rst(rst),.strobe(set_stb),.addr(set_addr),
      .in(set_data),.out(scale_factor),.changed());

   setting_reg #(.my_addr(BASE+2), .width(10)) sr_2
     (.clk(clk),.rst(rst),.strobe(set_stb),.addr(set_addr),
      .in(set_data),.out({enable_hb1, enable_hb2, cic_decim_rate}),.changed());

   setting_reg #(.my_addr(BASE+3), .width(2)) sr_3
     (.clk(clk),.rst(rst),.strobe(set_stb),.addr(set_addr),
      .in(set_data),.out({realmode,swap_iq}),.changed());

   // MUX so we can do realmode signals on either input
   
   always @(posedge clk)
     if(swap_iq)
       begin
	  rx_fe_i_mux <= rx_fe_q;
	  rx_fe_q_mux <= realmode ? 0 : rx_fe_i;
       end
     else
       begin
	  rx_fe_i_mux <= rx_fe_i;
	  rx_fe_q_mux <= realmode ? 0 : rx_fe_q;
       end

   // NCO
   always @(posedge clk)
     if(rst)
       phase <= 0;
     else if(~ddc_enb)
       phase <= 0;
     else
       phase <= phase + phase_inc;

   //sign extension of cordic input
   wire [WIDTH-1:0] to_ddc_chain_i, to_ddc_chain_q;
   wire [cwidth-1:0] to_cordic_i, to_cordic_q;
   sign_extend #(.bits_in(WIDTH), .bits_out(cwidth)) sign_extend_cordic_i (.in(to_ddc_chain_i), .out(to_cordic_i));
   sign_extend #(.bits_in(WIDTH), .bits_out(cwidth)) sign_extend_cordic_q (.in(to_ddc_chain_q), .out(to_cordic_q));

   // CORDIC  24-bit I/O
   cordic_z24 #(.bitwidth(cwidth))
     cordic(.clock(clk), .reset(rst), .enable(ddc_enb),
	    .xi(to_cordic_i),. yi(to_cordic_q), .zi(phase[31:32-zwidth]),
	    .xo(i_cordic),.yo(q_cordic),.zo() );

   clip_reg #(.bits_in(cwidth), .bits_out(WIDTH)) clip_i
     (.clk(clk), .in(i_cordic), .strobe_in(1'b1), .out(i_cordic_clip));
   clip_reg #(.bits_in(cwidth), .bits_out(WIDTH)) clip_q
     (.clk(clk), .in(q_cordic), .strobe_in(1'b1), .out(q_cordic_clip));

   // CIC decimator  24 bit I/O
   cic_strober cic_strober(.clock(clk),.reset(rst),.enable(ddc_enb),.rate(cic_decim_rate),
			   .strobe_fast(1),.strobe_slow(strobe_cic) );

   cic_decim #(.bw(WIDTH))
     decim_i (.clock(clk),.reset(rst),.enable(ddc_enb),
	      .rate(cic_decim_rate),.strobe_in(1'b1),.strobe_out(strobe_cic),
	      .signal_in(i_cordic_clip),.signal_out(i_cic));
   
   cic_decim #(.bw(WIDTH))
     decim_q (.clock(clk),.reset(rst),.enable(ddc_enb),
	      .rate(cic_decim_rate),.strobe_in(1'b1),.strobe_out(strobe_cic),
	      .signal_in(q_cordic_clip),.signal_out(q_cic));

   // First (small) halfband  24 bit I/O
   small_hb_dec #(.WIDTH(WIDTH)) small_hb_i
     (.clk(clk),.rst(rst),.bypass(~enable_hb1),.run(ddc_enb),
      .stb_in(strobe_cic),.data_in(i_cic),.stb_out(strobe_hb1),.data_out(i_hb1));
   
   small_hb_dec #(.WIDTH(WIDTH)) small_hb_q
     (.clk(clk),.rst(rst),.bypass(~enable_hb1),.run(ddc_enb),
      .stb_in(strobe_cic),.data_in(q_cic),.stb_out(),.data_out(q_hb1));

   // Second (large) halfband  24 bit I/O
   wire [8:0]  cpi_hb = enable_hb1 ? {cic_decim_rate,1'b0} : {1'b0,cic_decim_rate};
   hb_dec #(.WIDTH(WIDTH)) hb_i
     (.clk(clk),.rst(rst),.bypass(~enable_hb2),.run(ddc_enb),.cpi(cpi_hb),
      .stb_in(strobe_hb1),.data_in(i_hb1),.stb_out(strobe_hb2),.data_out(i_hb2));

   hb_dec #(.WIDTH(WIDTH)) hb_q
     (.clk(clk),.rst(rst),.bypass(~enable_hb2),.run(ddc_enb),.cpi(cpi_hb),
      .stb_in(strobe_hb1),.data_in(q_hb1),.stb_out(),.data_out(q_hb2));

   // round to 18 bits for multiplication (gain of 6 bits)
   wire [17:0] i_hb2_rnd, q_hb2_rnd;

   round #(.bits_in(WIDTH),.bits_out(18)) round_i_hb2 (.in(i_hb2), .out(i_hb2_rnd));
   round #(.bits_in(WIDTH),.bits_out(18)) round_q_hb2 (.in(q_hb2), .out(q_hb2_rnd));

   //scalar operation
   wire [35:0] prod_i, prod_q;

   MULT18X18S mult_i
     (.P(prod_i), .A(i_hb2_rnd), .B(scale_factor), .C(clk), .CE(strobe_hb2), .R(rst) );
   MULT18X18S mult_q
     (.P(prod_q), .A(q_hb2_rnd), .B(scale_factor), .C(clk), .CE(strobe_hb2), .R(rst) );

   //pipeline for the multiplier with clipping to 34 bits
   wire [33:0] prod_reg_i, prod_reg_q;
   wire strobe_mult;
   clip_reg #(.bits_in(36),.bits_out(34)) clip_prod_i
     (.clk(clk),.in(prod_i),.out(prod_reg_i),.strobe_in(strobe_hb2),.strobe_out(strobe_mult));
   clip_reg #(.bits_in(36),.bits_out(34)) clip_prod_q
     (.clk(clk),.in(prod_q),.out(prod_reg_q),.strobe_in(strobe_hb2),.strobe_out());

   // Round final answer to 16 bits
   wire [31:0] ddc_chain_out;
   wire ddc_chain_stb;

   round_sd #(.WIDTH_IN(34),.WIDTH_OUT(16)) round_i
     (.clk(clk),.reset(rst), .in(prod_reg_i),.strobe_in(strobe_mult), .out(ddc_chain_out[31:16]), .strobe_out(ddc_chain_stb));

   round_sd #(.WIDTH_IN(34),.WIDTH_OUT(16)) round_q
     (.clk(clk),.reset(rst), .in(prod_reg_q),.strobe_in(strobe_mult), .out(ddc_chain_out[15:0]), .strobe_out());

   dsp_rx_glue #(.DSPNO(DSPNO), .WIDTH(WIDTH)) custom(
    .clock(clk), .reset(rst), .clear(clr), .enable(run),
    .set_stb(set_stb_user), .set_addr(set_addr_user), .set_data(set_data_user),
    .frontend_i(rx_fe_i_mux), .frontend_q(rx_fe_q_mux),
    .ddc_in_i(to_ddc_chain_i), .ddc_in_q(to_ddc_chain_q),
    .ddc_out_sample(ddc_chain_out), .ddc_out_strobe(ddc_chain_stb), .ddc_out_enable(ddc_enb),
    .bb_sample(sample), .bb_strobe(strobe));

   assign      debug = {enable_hb1, enable_hb2, run, strobe, strobe_cic, strobe_hb1, strobe_hb2};
   
endmodule // ddc_chain