yosys/techlibs/xilinx/cells_map.v


module  \$_DFF_N_ (input D, C, output Q); FDRE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_R_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .R(1'b0)); endmodule
module  \$_DFF_P_ (input D, C, output Q); FDRE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_R_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .R(1'b0)); endmodule

module  \$_DFFE_NP_ (input D, C, E, output Q); FDRE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_R_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(E), .R(1'b0)); endmodule
module  \$_DFFE_PP_ (input D, C, E, output Q); FDRE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_R_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(E), .R(1'b0)); endmodule

module  \$_DFF_NN0_ (input D, C, R, output Q); FDCE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_CLR_INVERTED(|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule
module  \$_DFF_NP0_ (input D, C, R, output Q); FDCE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_CLR_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule
module  \$_DFF_PN0_ (input D, C, R, output Q); FDCE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_CLR_INVERTED(|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule
module  \$_DFF_PP0_ (input D, C, R, output Q); FDCE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_CLR_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule

module  \$_DFF_NN1_ (input D, C, R, output Q); FDPE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_PRE_INVERTED(|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule
module  \$_DFF_NP1_ (input D, C, R, output Q); FDPE #(.INIT(|0), .IS_C_INVERTED(|1), .IS_D_INVERTED(|0), .IS_PRE_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule
module  \$_DFF_PN1_ (input D, C, R, output Q); FDPE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_PRE_INVERTED(|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule
module  \$_DFF_PP1_ (input D, C, R, output Q); FDPE #(.INIT(|0), .IS_C_INVERTED(|0), .IS_D_INVERTED(|0), .IS_PRE_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule

`ifndef NO_LUT
module \$lut (A, Y);
  parameter WIDTH = 0;
  parameter LUT = 0;

  input [WIDTH-1:0] A;
  output Y;

  generate
    if (WIDTH == 1) begin
      LUT1 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]));
    end else
    if (WIDTH == 2) begin
      LUT2 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]), .I1(A[1]));
    end else
    if (WIDTH == 3) begin
      LUT3 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]), .I1(A[1]), .I2(A[2]));
    end else
    if (WIDTH == 4) begin
      LUT4 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]));
    end else
    if (WIDTH == 5) begin
      LUT5 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]));
    end else
    if (WIDTH == 6) begin
      LUT6 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
    end else
    if (WIDTH == 7) begin
      wire T0, T1;
      LUT6 #(.INIT(LUT[63:0])) fpga_lut_0 (.O(T0),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      LUT6 #(.INIT(LUT[127:64])) fpga_lut_1 (.O(T1),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      MUXF7 fpga_mux_0 (.O(Y), .I0(T0), .I1(T1), .S(A[6]));
    end else
    if (WIDTH == 8) begin
      wire T0, T1, T2, T3, T4, T5;
      LUT6 #(.INIT(LUT[63:0])) fpga_lut_0 (.O(T0),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      LUT6 #(.INIT(LUT[127:64])) fpga_lut_1 (.O(T1),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      LUT6 #(.INIT(LUT[191:128])) fpga_lut_2 (.O(T2),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      LUT6 #(.INIT(LUT[255:192])) fpga_lut_3 (.O(T3),
        .I0(A[0]), .I1(A[1]), .I2(A[2]),
        .I3(A[3]), .I4(A[4]), .I5(A[5]));
      MUXF7 fpga_mux_0 (.O(T4), .I0(T0), .I1(T1), .S(A[6]));
      MUXF7 fpga_mux_1 (.O(T5), .I0(T2), .I1(T3), .S(A[6]));
      MUXF8 fpga_mux_2 (.O(Y), .I0(T4), .I1(T5), .S(A[7]));
    end else begin
      wire _TECHMAP_FAIL_ = 1;
    end
  endgenerate
endmodule
`endif

module \$__SHREG_ (input C, input D, input E, output Q);
  parameter DEPTH = 0;
  parameter [DEPTH-1:0] INIT = 0;
  parameter CLKPOL = 1;
  parameter ENPOL = 2;
  wire CE;
  generate
    if (ENPOL == 0)
      assign CE = ~E;
    else if (ENPOL == 1)
      assign CE = E;
    else
      assign CE = 1'b1;
    if (DEPTH == 1) begin
        FDRE #(.INIT(INIT), .IS_C_INVERTED(~CLKPOL[0]), .IS_D_INVERTED(|0), .IS_R_INVERTED(|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(CE), .R(1'b0));
    end else
    if (DEPTH <= 16) begin
      localparam [3:0] A = DEPTH - 1;
      SRL16E #(.INIT(INIT), .IS_CLK_INVERTED(~CLKPOL[0])) _TECHMAP_REPLACE_ (.A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .CE(CE), .CLK(C), .D(D), .Q(Q));
    end else
    if (DEPTH == 17) begin
      wire T0;
      \$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));
      \$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));
    end else
    if (DEPTH <= 32) begin
      SRLC32E #(.INIT(INIT), .IS_CLK_INVERTED(~CLKPOL[0])) _TECHMAP_REPLACE_ (.A(DEPTH-1), .CE(CE), .CLK(C), .D(D), .Q(Q));
    end else
    if (DEPTH == 33 || DEPTH == 49) begin
      wire T0;
      \$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));
      \$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));
    end else
    if (DEPTH <= 64) begin
      wire T0, T1, T2;
      localparam [5:0] A = DEPTH-1;
      SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));
      \$__SHREG_ #(.DEPTH(DEPTH-32), .INIT(INIT[DEPTH-1:32]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T1), .E(E), .Q(T2));
      MUXF7 fpga_mux_0 (.O(Q), .I0(T0), .I1(T2), .S(A[5]));
    end else
    if (DEPTH == 65 || DEPTH == 81) begin
      wire T0;
      \$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));
      \$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));
    end else
    if (DEPTH <= 96) begin
      localparam [6:0] A = DEPTH-1;
      wire T0, T1, T2, T3, T4, T5, T6;
      SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));
      SRLC32E #(.INIT(INIT[64-1:32]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_1 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T1), .Q(T2), .Q31(T3));
      \$__SHREG_ #(.DEPTH(DEPTH-64), .INIT(INIT[DEPTH-1:64]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_2 (.C(C), .D(T3), .E(E), .Q(T4));
      MUXF7 fpga_mux_0 (.O(T5), .I0(T0), .I1(T2), .S(A[5]));
      MUXF7 fpga_mux_1 (.O(T6), .I0(T4), .I1(1'b0 /* unused */), .S(A[5]));
      MUXF8 fpga_mux_2 (.O(Q), .I0(T5), .I1(T6), .S(A[6]));
    end else
    if (DEPTH == 97 || DEPTH == 113) begin
      wire T0;
      \$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));
      \$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));
    end else
    if (DEPTH <= 128) begin
      localparam [6:0] A = DEPTH-1;
      wire T0, T1, T2, T3, T4, T5, T6, T7, T8;
      SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));
      SRLC32E #(.INIT(INIT[64-1:32]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_1 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T1), .Q(T2), .Q31(T3));
      SRLC32E #(.INIT(INIT[96-1:64]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_2 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T3), .Q(T4), .Q31(T5));
      \$__SHREG_ #(.DEPTH(DEPTH-96), .INIT(INIT[DEPTH-1:96]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_3 (.C(C), .D(T5), .E(E), .Q(T6));
      MUXF7 fpga_mux_0 (.O(T7), .I0(T0), .I1(T2), .S(A[5]));
      MUXF7 fpga_mux_1 (.O(T8), .I0(T4), .I1(T6), .S(A[5]));
      MUXF8 fpga_mux_2 (.O(Q), .I0(T7), .I1(T8), .S(A[6]));
    end else
    begin
      wire T0, T1;
      \$__SHREG_ #(.DEPTH(128), .INIT(INIT[128-1:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));
      \$__SHREG_ #(.DEPTH(DEPTH-128), .INIT(INIT[DEPTH-1:128]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));
    end
  endgenerate
endmodule
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`module \$_DFF_N_ (input D, C, output Q); FDRE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_R_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .R(1'b0)); endmodule`
			`module \$_DFF_P_ (input D, C, output Q); FDRE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_R_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .R(1'b0)); endmodule`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`module \$_DFFE_NP_ (input D, C, E, output Q); FDRE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_R_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(E), .R(1'b0)); endmodule`
			`module \$_DFFE_PP_ (input D, C, E, output Q); FDRE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_R_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(E), .R(1'b0)); endmodule`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`module \$_DFF_NN0_ (input D, C, R, output Q); FDCE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_CLR_INVERTED(\|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule`
			`module \$_DFF_NP0_ (input D, C, R, output Q); FDCE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_CLR_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule`
			`module \$_DFF_PN0_ (input D, C, R, output Q); FDCE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_CLR_INVERTED(\|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule`
			`module \$_DFF_PP0_ (input D, C, R, output Q); FDCE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_CLR_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .CLR(R)); endmodule`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`module \$_DFF_NN1_ (input D, C, R, output Q); FDPE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_PRE_INVERTED(\|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule`
			`module \$_DFF_NP1_ (input D, C, R, output Q); FDPE #(.INIT(\|0), .IS_C_INVERTED(\|1), .IS_D_INVERTED(\|0), .IS_PRE_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule`
			`module \$_DFF_PN1_ (input D, C, R, output Q); FDPE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_PRE_INVERTED(\|1)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule`
			`module \$_DFF_PP1_ (input D, C, R, output Q); FDPE #(.INIT(\|0), .IS_C_INVERTED(\|0), .IS_D_INVERTED(\|0), .IS_PRE_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(1'b1), .PRE(R)); endmodule`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
Improving vpr output support. * Support output BLIF for Xilinx architectures. * Support using .names in BLIF for Xilinx architectures. * Use the same `NO_LUT` define in both `synth_ice40` and `synth_xilinx`. 2018-04-18 18:48:05 -05:00			`ifndef NO_LUT
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`module \$lut (A, Y);`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`parameter WIDTH = 0;`
			`parameter LUT = 0;`

Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`input [WIDTH-1:0] A;`
			`output Y;`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00
			`generate`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 1) begin`
			`LUT1 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]));`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 2) begin`
			`LUT2 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]), .I1(A[1]));`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 3) begin`
			`LUT3 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]), .I1(A[1]), .I2(A[2]));`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 4) begin`
			`LUT4 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]));`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 5) begin`
			`LUT5 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]));`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 6) begin`
			`LUT6 #(.INIT(LUT)) _TECHMAP_REPLACE_ (.O(Y),`
Renamed $lut ports to follow A-Y naming scheme 2014-08-15 07:18:40 -05:00			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
Added Xilinx MUXF7 and MUXF8 support 2015-01-15 06:50:04 -06:00			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 7) begin`
Added Xilinx MUXF7 and MUXF8 support 2015-01-15 06:50:04 -06:00			`wire T0, T1;`
			`LUT6 #(.INIT(LUT[63:0])) fpga_lut_0 (.O(T0),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`LUT6 #(.INIT(LUT[127:64])) fpga_lut_1 (.O(T1),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`MUXF7 fpga_mux_0 (.O(Y), .I0(T0), .I1(T1), .S(A[6]));`
			`end else`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`if (WIDTH == 8) begin`
Added Xilinx MUXF7 and MUXF8 support 2015-01-15 06:50:04 -06:00			`wire T0, T1, T2, T3, T4, T5;`
			`LUT6 #(.INIT(LUT[63:0])) fpga_lut_0 (.O(T0),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`LUT6 #(.INIT(LUT[127:64])) fpga_lut_1 (.O(T1),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`LUT6 #(.INIT(LUT[191:128])) fpga_lut_2 (.O(T2),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`LUT6 #(.INIT(LUT[255:192])) fpga_lut_3 (.O(T3),`
			`.I0(A[0]), .I1(A[1]), .I2(A[2]),`
			`.I3(A[3]), .I4(A[4]), .I5(A[5]));`
			`MUXF7 fpga_mux_0 (.O(T4), .I0(T0), .I1(T1), .S(A[6]));`
			`MUXF7 fpga_mux_1 (.O(T5), .I0(T2), .I1(T3), .S(A[6]));`
			`MUXF8 fpga_mux_2 (.O(Y), .I0(T4), .I1(T5), .S(A[7]));`
Added more FF types to xilinx/cells.v 2015-01-16 08:24:54 -06:00			`end else begin`
Added more generic _TECHMAP_ wire mechanism to techmap pass 2013-11-23 08:58:06 -06:00			`wire _TECHMAP_FAIL_ = 1;`
Added simple xilinx7 technology mapping files 2013-08-22 13:26:19 -05:00			`end`
			`endgenerate`
			`endmodule`
Improving vpr output support. * Support output BLIF for Xilinx architectures. * Support using .names in BLIF for Xilinx architectures. * Use the same `NO_LUT` define in both `synth_ice40` and `synth_xilinx`. 2018-04-18 18:48:05 -05:00			`endif
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`module \$__SHREG_ (input C, input D, input E, output Q);`
synth_xilinx to use shregmap with -params too 2019-02-28 12:21:05 -06:00			`parameter DEPTH = 0;`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`parameter [DEPTH-1:0] INIT = 0;`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`parameter CLKPOL = 1;`
synth_xilinx to use shregmap with -params too 2019-02-28 12:21:05 -06:00			`parameter ENPOL = 2;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`wire CE;`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`generate`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`if (ENPOL == 0)`
			`assign CE = ~E;`
			`else if (ENPOL == 1)`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`assign CE = E;`
			`else`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`assign CE = 1'b1;`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`if (DEPTH == 1) begin`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`FDRE #(.INIT(INIT), .IS_C_INVERTED(~CLKPOL[0]), .IS_D_INVERTED(\|0), .IS_R_INVERTED(\|0)) _TECHMAP_REPLACE_ (.D(D), .Q(Q), .C(C), .CE(CE), .R(1'b0));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH <= 16) begin`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`localparam [3:0] A = DEPTH - 1;`
			`SRL16E #(.INIT(INIT), .IS_CLK_INVERTED(~CLKPOL[0])) _TECHMAP_REPLACE_ (.A0(A[0]), .A1(A[1]), .A2(A[2]), .A3(A[3]), .CE(CE), .CLK(C), .D(D), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH == 17) begin`
			`wire T0;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));`
			`\$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH <= 32) begin`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`SRLC32E #(.INIT(INIT), .IS_CLK_INVERTED(~CLKPOL[0])) _TECHMAP_REPLACE_ (.A(DEPTH-1), .CE(CE), .CLK(C), .D(D), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH == 33 \|\| DEPTH == 49) begin`
			`wire T0;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));`
			`\$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH <= 64) begin`
			`wire T0, T1, T2;`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`localparam [5:0] A = DEPTH-1;`
			`SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-32), .INIT(INIT[DEPTH-1:32]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T1), .E(E), .Q(T2));`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`MUXF7 fpga_mux_0 (.O(Q), .I0(T0), .I1(T2), .S(A[5]));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH == 65 \|\| DEPTH == 81) begin`
			`wire T0;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));`
			`\$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH <= 96) begin`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`localparam [6:0] A = DEPTH-1;`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`wire T0, T1, T2, T3, T4, T5, T6;`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));`
			`SRLC32E #(.INIT(INIT[64-1:32]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_1 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T1), .Q(T2), .Q31(T3));`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-64), .INIT(INIT[DEPTH-1:64]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_2 (.C(C), .D(T3), .E(E), .Q(T4));`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`MUXF7 fpga_mux_0 (.O(T5), .I0(T0), .I1(T2), .S(A[5]));`
			`MUXF7 fpga_mux_1 (.O(T6), .I0(T4), .I1(1'b0 /* unused */), .S(A[5]));`
			`MUXF8 fpga_mux_2 (.O(Q), .I0(T5), .I1(T6), .S(A[6]));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH == 97 \|\| DEPTH == 113) begin`
			`wire T0;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-1), .INIT(INIT[DEPTH-2:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));`
			`\$__SHREG_ #(.DEPTH(1), .INIT(INIT[DEPTH-1]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`if (DEPTH <= 128) begin`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`localparam [6:0] A = DEPTH-1;`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`wire T0, T1, T2, T3, T4, T5, T6, T7, T8;`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`SRLC32E #(.INIT(INIT[32-1:0]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_0 (.A(A[4:0]), .CE(CE), .CLK(C), .D(D), .Q(T0), .Q31(T1));`
			`SRLC32E #(.INIT(INIT[64-1:32]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_1 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T1), .Q(T2), .Q31(T3));`
			`SRLC32E #(.INIT(INIT[96-1:64]), .IS_CLK_INVERTED(~CLKPOL[0])) fpga_srl_2 (.A(A[4:0]), .CE(CE), .CLK(C), .D(T3), .Q(T4), .Q31(T5));`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(DEPTH-96), .INIT(INIT[DEPTH-1:96]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_3 (.C(C), .D(T5), .E(E), .Q(T6));`
Fix SRL16/32 techmap off-by-one 2019-02-28 15:56:00 -06:00			`MUXF7 fpga_mux_0 (.O(T7), .I0(T0), .I1(T2), .S(A[5]));`
			`MUXF7 fpga_mux_1 (.O(T8), .I0(T4), .I1(T6), .S(A[5]));`
			`MUXF8 fpga_mux_2 (.O(Q), .I0(T7), .I1(T8), .S(A[6]));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end else`
			`begin`
			`wire T0, T1;`
synth_xilinx to call shregmap with enable support 2019-02-28 13:17:13 -06:00			`\$__SHREG_ #(.DEPTH(128), .INIT(INIT[128-1:0]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_0 (.C(C), .D(D), .E(E), .Q(T0));`
			`\$__SHREG_ #(.DEPTH(DEPTH-128), .INIT(INIT[DEPTH-1:128]), .CLKPOL(CLKPOL), .ENPOL(ENPOL)) fpga_srl_1 (.C(C), .D(T0), .E(E), .Q(Q));`
Add techmap rule for $__SHREG_DFF_P_ to SRL16/32 2019-02-28 11:31:24 -06:00			`end`
			`endgenerate`
			`endmodule`