// Copyright 2014 Ettus Research // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: LGPL-3.0-or-later // Write xilinx DSP48E1 primitive for mult-add with AXI interfaces module mult_add #(parameter WIDTH_A=25, parameter WIDTH_B=18, parameter WIDTH_P=48, // Must be 48 if you are cascading parameter DROP_TOP_P=0, // Must be 0 if you are cascading parameter LATENCY=3, parameter CASCADE_IN=0, parameter CASCADE_OUT=0) (input clk, input reset, input [WIDTH_A-1:0] a_tdata, input a_tlast, input a_tvalid, output a_tready, input [WIDTH_B-1:0] b_tdata, input b_tlast, input b_tvalid, output b_tready, input [WIDTH_P-1:0] c_tdata, input c_tlast, input c_tvalid, output c_tready, output [WIDTH_P-1:0] p_tdata, output p_tlast, output p_tvalid, input p_tready); wire [24:0] A_IN = { a_tdata, {(25-(WIDTH_A)){1'b0}}}; wire [17:0] B_IN = { b_tdata, {(18-(WIDTH_B)){1'b0}}}; wire [47:0] P1_OUT, P1_OUT_CASC; wire [47:0] p_tdata_int = CASCADE_OUT ? P1_OUT_CASC : P1_OUT; assign p_tdata = p_tdata_int[47-DROP_TOP_P:48-WIDTH_P-DROP_TOP_P]; wire [47:0] c_tdata_int = { {DROP_TOP_P{c_tdata[WIDTH_P-1]}}, c_tdata, {(48-WIDTH_P-DROP_TOP_P){1'b0}} }; wire [47:0] CIN = CASCADE_IN ? 48'h0000_0000_0000 : c_tdata_int; wire [47:0] PCIN = CASCADE_IN ? c_tdata_int : 48'h0000_0000_0000; localparam MREG_IN = 1; // Always have this reg localparam PREG_IN = (LATENCY >= 3) ? 1 : 0; localparam A2REG_IN = (LATENCY >= 2) ? 1 : 0; localparam A1REG_IN = (LATENCY == 4) ? 1 : 0; localparam AREG_IN = A1REG_IN + A2REG_IN; // See OPMODE Control Bits Settings, Table 2-7,2-8,2-9 localparam ZMUX_PCIN = 3'b001; localparam ZMUX_C = 3'b011; localparam XMUX_M = 2'b01; localparam YMUX_M = 2'b01; wire [A1REG_IN:0] enables_a, enables_b; wire enable_c, enable_m; wire [PREG_IN:0] en_post; wire CE = 1'b1; // FIXME wire LOAD = 1'b1; wire CEC, CEM, CEP; reg CEA2, CEA1, CEB2, CEB1; always @* case(LATENCY) 3 : {CEA2, CEA1, CEB2, CEB1} <= { enables_a[0], 1'b0 , enables_b[0], 1'b0 }; 4 : {CEA2, CEA1, CEB2, CEB1} <= { enables_a[1], enables_a[0], enables_b[1], enables_b[0] }; endcase axi_pipe_mac #(.LATENCY(LATENCY), .CASCADE_IN(CASCADE_IN)) axi_pipe_mac (.clk(clk), .reset(reset), .clear(1'b0), .a_tlast(a_tlast), .a_tvalid(a_tvalid), .a_tready(a_tready), .b_tlast(b_tlast), .b_tvalid(b_tvalid), .b_tready(b_tready), .c_tlast(c_tlast), .c_tvalid(c_tvalid), .c_tready(c_tready), .p_tlast(p_tlast), .p_tvalid(p_tvalid), .p_tready(p_tready), .enables_a(enables_a), .enables_b(enables_b), .enable_c(CEC), .enable_m(CEM), .enable_p(CEP)); DSP48E1 #(.ACASCREG(AREG_IN), .AREG(AREG_IN), .ADREG(0), .DREG(0), .BCASCREG(AREG_IN), .BREG(AREG_IN), .MREG(MREG_IN), .PREG(PREG_IN)) DSP48_inst (.ACOUT(), // Outputs start here .BCOUT(), .CARRYCASCOUT(), .CARRYOUT(), .MULTSIGNOUT(), .OVERFLOW(), .P(P1_OUT), .PATTERNBDETECT(), .PATTERNDETECT(), .PCOUT(P1_OUT_CASC), .UNDERFLOW(), .A({5'b0,A_IN}), // Inputs start here .ACIN(30'b0), .ALUMODE(4'b0000), ////////////////////// .B(B_IN), .BCIN(18'b0), .C(CIN), /////////////////////// .CARRYCASCIN(1'b0), .CARRYIN(1'b0), .CARRYINSEL(3'b0), .CEA1(CEA1), .CEA2(CEA2), .CEAD(1'b0), .CEALUMODE(1'b1), //////////////////////// .CEB1(CEB1), .CEB2(CEB2), .CEC(CEC), /////////////////////////// .CECARRYIN(CE), .CECTRL(CE), .CED(CE), .CEINMODE(CE), .CEM(CEM), .CEP(CEP), .CLK(clk), .D(25'b0), .INMODE(5'b0), /////////////////////// .MULTSIGNIN(1'b0), .OPMODE({(CASCADE_IN ? ZMUX_PCIN : ZMUX_C), YMUX_M, XMUX_M}), // //////////////////// .PCIN(PCIN), ////////////////////// .RSTA(reset), .RSTALLCARRYIN(reset), .RSTALUMODE(reset), .RSTB(reset), .RSTC(reset), .RSTD(reset), .RSTCTRL(reset), .RSTINMODE(reset), .RSTM(reset), .RSTP(reset)); endmodule // mult