wangxinze/Verilog_data · Datasets at Hugging Face

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module generic_baseblocks_v2_1_mux # ( parameter C_FAMILY = "rtl", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_SEL_WIDTH = 4, // Data width for comparator. parameter integer C_DATA_WIDTH = 2 // Data width for comparator. ) ( input wire [C_SEL_WIDTH-1:0] S, input wire [(2*C_SEL_WIDTH)C_DATA_WIDTH-1:0] A, output wire [C_DATA_WIDTH-1:0] O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar bit_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" \|\| C_SEL_WIDTH < 3 ) begin : USE_RTL assign O = A[(S)C_DATA_WIDTH +: C_DATA_WIDTH]; end else begin : USE_FPGA wire [C_DATA_WIDTH-1:0] C; wire [C_DATA_WIDTH-1:0] D; // Lower half recursively. generic_baseblocks_v2_1_mux # ( .C_FAMILY (C_FAMILY), .C_SEL_WIDTH (C_SEL_WIDTH-1), .C_DATA_WIDTH (C_DATA_WIDTH) ) mux_c_inst ( .S (S[C_SEL_WIDTH-2:0]), .A (A[(2(C_SEL_WIDTH-1))C_DATA_WIDTH-1 : 0]), .O (C) ); // Upper half recursively. generic_baseblocks_v2_1_mux # ( .C_FAMILY (C_FAMILY), .C_SEL_WIDTH (C_SEL_WIDTH-1), .C_DATA_WIDTH (C_DATA_WIDTH) ) mux_d_inst ( .S (S[C_SEL_WIDTH-2:0]), .A (A[(2*C_SEL_WIDTH)C_DATA_WIDTH-1 : (2*(C_SEL_WIDTH-1))C_DATA_WIDTH]), .O (D) ); // Generate instantiated generic_baseblocks_v2_1_mux components as required. for (bit_cnt = 0; bit_cnt < C_DATA_WIDTH ; bit_cnt = bit_cnt + 1) begin : NUM if ( C_SEL_WIDTH == 4 ) begin : USE_F8 MUXF8 muxf8_inst ( .I0 (C[bit_cnt]), .I1 (D[bit_cnt]), .S (S[C_SEL_WIDTH-1]), .O (O[bit_cnt]) ); end else if ( C_SEL_WIDTH == 3 ) begin : USE_F7 MUXF7 muxf7_inst ( .I0 (C[bit_cnt]), .I1 (D[bit_cnt]), .S (S[C_SEL_WIDTH-1]), .O (O[bit_cnt]) ); end // C_SEL_WIDTH end // end for bit_cnt end endgenerate endmodule
module generic_baseblocks_v2_1_comparator_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar bit_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 6; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (bit_cnt = 0; bit_cnt < C_NUM_LUT ; bit_cnt = bit_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[bit_cnt] = ( a_local[bit_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] == b_local[bit_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[bit_cnt+1]), .CIN (carry_local[bit_cnt]), .S (sel[bit_cnt]) ); end // end for bit_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar bit_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 6; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (bit_cnt = 0; bit_cnt < C_NUM_LUT ; bit_cnt = bit_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[bit_cnt] = ( a_local[bit_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] == b_local[bit_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[bit_cnt+1]), .CIN (carry_local[bit_cnt]), .S (sel[bit_cnt]) ); end // end for bit_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_nto1_mux # ( parameter integer C_RATIO = 1, // Range: >=1 parameter integer C_SEL_WIDTH = 1, // Range: >=1; recommended: ceil_log2(C_RATIO) parameter integer C_DATAOUT_WIDTH = 1, // Range: >=1 parameter integer C_ONEHOT = 0 // Values: 0 = binary-encoded (use SEL); 1 = one-hot (use SEL_ONEHOT) ) ( input wire [C_RATIO-1:0] SEL_ONEHOT, // One-hot generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=1) input wire [C_SEL_WIDTH-1:0] SEL, // Binary-encoded generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=0) input wire [C_RATIOC_DATAOUT_WIDTH-1:0] IN, // Data input array (num_selections x data_width) output wire [C_DATAOUT_WIDTH-1:0] OUT // Data output vector ); wire [C_DATAOUT_WIDTHC_RATIO-1:0] carry; genvar i; generate if (C_ONEHOT == 0) begin : gen_encoded assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{(SEL==0)?1'b1:1'b0}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_enc assign carry[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH] = carry[iC_DATAOUT_WIDTH-1:(i-1)C_DATAOUT_WIDTH] \| {C_DATAOUT_WIDTH{(SEL==i)?1'b1:1'b0}} & IN[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH]; end end else begin : gen_onehot assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{SEL_ONEHOT[0]}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_hot assign carry[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH] = carry[iC_DATAOUT_WIDTH-1:(i-1)C_DATAOUT_WIDTH] \| {C_DATAOUT_WIDTH{SEL_ONEHOT[i]}} & IN[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH]; end end endgenerate assign OUT = carry[C_DATAOUT_WIDTHC_RATIO-1: C_DATAOUT_WIDTH(C_RATIO-1)]; endmodule
module generic_baseblocks_v2_1_nto1_mux # ( parameter integer C_RATIO = 1, // Range: >=1 parameter integer C_SEL_WIDTH = 1, // Range: >=1; recommended: ceil_log2(C_RATIO) parameter integer C_DATAOUT_WIDTH = 1, // Range: >=1 parameter integer C_ONEHOT = 0 // Values: 0 = binary-encoded (use SEL); 1 = one-hot (use SEL_ONEHOT) ) ( input wire [C_RATIO-1:0] SEL_ONEHOT, // One-hot generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=1) input wire [C_SEL_WIDTH-1:0] SEL, // Binary-encoded generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=0) input wire [C_RATIOC_DATAOUT_WIDTH-1:0] IN, // Data input array (num_selections x data_width) output wire [C_DATAOUT_WIDTH-1:0] OUT // Data output vector ); wire [C_DATAOUT_WIDTHC_RATIO-1:0] carry; genvar i; generate if (C_ONEHOT == 0) begin : gen_encoded assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{(SEL==0)?1'b1:1'b0}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_enc assign carry[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH] = carry[iC_DATAOUT_WIDTH-1:(i-1)C_DATAOUT_WIDTH] \| {C_DATAOUT_WIDTH{(SEL==i)?1'b1:1'b0}} & IN[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH]; end end else begin : gen_onehot assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{SEL_ONEHOT[0]}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_hot assign carry[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH] = carry[iC_DATAOUT_WIDTH-1:(i-1)C_DATAOUT_WIDTH] \| {C_DATAOUT_WIDTH{SEL_ONEHOT[i]}} & IN[(i+1)C_DATAOUT_WIDTH-1:iC_DATAOUT_WIDTH]; end end endgenerate assign OUT = carry[C_DATAOUT_WIDTHC_RATIO-1: C_DATAOUT_WIDTH(C_RATIO-1)]; endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_carry_and # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN & S; end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b0), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_and # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN & S; end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b0), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_and # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN & S; end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b0), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN \| S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN \| I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN \| I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN \| I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN \| I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN \| I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) \| (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) \| (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) \| (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) \| (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) \| (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule
module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule

module generic_baseblocks_v2_1_mux # ( parameter C_FAMILY = "rtl", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_SEL_WIDTH = 4, // Data width for comparator. parameter integer C_DATA_WIDTH = 2 // Data width for comparator. ) ( input wire [C_SEL_WIDTH-1:0] S, input wire [(2**C_SEL_WIDTH)*C_DATA_WIDTH-1:0] A, output wire [C_DATA_WIDTH-1:0] O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar bit_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" || C_SEL_WIDTH < 3 ) begin : USE_RTL assign O = A[(S)*C_DATA_WIDTH +: C_DATA_WIDTH]; end else begin : USE_FPGA wire [C_DATA_WIDTH-1:0] C; wire [C_DATA_WIDTH-1:0] D; // Lower half recursively. generic_baseblocks_v2_1_mux # ( .C_FAMILY (C_FAMILY), .C_SEL_WIDTH (C_SEL_WIDTH-1), .C_DATA_WIDTH (C_DATA_WIDTH) ) mux_c_inst ( .S (S[C_SEL_WIDTH-2:0]), .A (A[(2**(C_SEL_WIDTH-1))*C_DATA_WIDTH-1 : 0]), .O (C) ); // Upper half recursively. generic_baseblocks_v2_1_mux # ( .C_FAMILY (C_FAMILY), .C_SEL_WIDTH (C_SEL_WIDTH-1), .C_DATA_WIDTH (C_DATA_WIDTH) ) mux_d_inst ( .S (S[C_SEL_WIDTH-2:0]), .A (A[(2**C_SEL_WIDTH)*C_DATA_WIDTH-1 : (2**(C_SEL_WIDTH-1))*C_DATA_WIDTH]), .O (D) ); // Generate instantiated generic_baseblocks_v2_1_mux components as required. for (bit_cnt = 0; bit_cnt < C_DATA_WIDTH ; bit_cnt = bit_cnt + 1) begin : NUM if ( C_SEL_WIDTH == 4 ) begin : USE_F8 MUXF8 muxf8_inst ( .I0 (C[bit_cnt]), .I1 (D[bit_cnt]), .S (S[C_SEL_WIDTH-1]), .O (O[bit_cnt]) ); end else if ( C_SEL_WIDTH == 3 ) begin : USE_F7 MUXF7 muxf7_inst ( .I0 (C[bit_cnt]), .I1 (D[bit_cnt]), .S (S[C_SEL_WIDTH-1]), .O (O[bit_cnt]) ); end // C_SEL_WIDTH end // end for bit_cnt end endgenerate endmodule

module generic_baseblocks_v2_1_comparator_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar bit_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 6; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (bit_cnt = 0; bit_cnt < C_NUM_LUT ; bit_cnt = bit_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[bit_cnt] = ( a_local[bit_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] == b_local[bit_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[bit_cnt+1]), .CIN (carry_local[bit_cnt]), .S (sel[bit_cnt]) ); end // end for bit_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule

module generic_baseblocks_v2_1_nto1_mux # ( parameter integer C_RATIO = 1, // Range: >=1 parameter integer C_SEL_WIDTH = 1, // Range: >=1; recommended: ceil_log2(C_RATIO) parameter integer C_DATAOUT_WIDTH = 1, // Range: >=1 parameter integer C_ONEHOT = 0 // Values: 0 = binary-encoded (use SEL); 1 = one-hot (use SEL_ONEHOT) ) ( input wire [C_RATIO-1:0] SEL_ONEHOT, // One-hot generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=1) input wire [C_SEL_WIDTH-1:0] SEL, // Binary-encoded generic_baseblocks_v2_1_mux select (only used if C_ONEHOT=0) input wire [C_RATIO*C_DATAOUT_WIDTH-1:0] IN, // Data input array (num_selections x data_width) output wire [C_DATAOUT_WIDTH-1:0] OUT // Data output vector ); wire [C_DATAOUT_WIDTH*C_RATIO-1:0] carry; genvar i; generate if (C_ONEHOT == 0) begin : gen_encoded assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{(SEL==0)?1'b1:1'b0}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_enc assign carry[(i+1)*C_DATAOUT_WIDTH-1:i*C_DATAOUT_WIDTH] = carry[i*C_DATAOUT_WIDTH-1:(i-1)*C_DATAOUT_WIDTH] | {C_DATAOUT_WIDTH{(SEL==i)?1'b1:1'b0}} & IN[(i+1)*C_DATAOUT_WIDTH-1:i*C_DATAOUT_WIDTH]; end end else begin : gen_onehot assign carry[C_DATAOUT_WIDTH-1:0] = {C_DATAOUT_WIDTH{SEL_ONEHOT[0]}} & IN[C_DATAOUT_WIDTH-1:0]; for (i=1;i<C_RATIO;i=i+1) begin : gen_carrychain_hot assign carry[(i+1)*C_DATAOUT_WIDTH-1:i*C_DATAOUT_WIDTH] = carry[i*C_DATAOUT_WIDTH-1:(i-1)*C_DATAOUT_WIDTH] | {C_DATAOUT_WIDTH{SEL_ONEHOT[i]}} & IN[(i+1)*C_DATAOUT_WIDTH-1:i*C_DATAOUT_WIDTH]; end end endgenerate assign OUT = carry[C_DATAOUT_WIDTH*C_RATIO-1: C_DATAOUT_WIDTH*(C_RATIO-1)]; endmodule

module generic_baseblocks_v2_1_comparator_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 2; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( a_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( b_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule

module generic_baseblocks_v2_1_carry_and # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN & S; end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b0), .S (S) ); end endgenerate endmodule

module generic_baseblocks_v2_1_carry_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = CIN | S; end else begin : USE_FPGA wire S_n; assign S_n = ~S; MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (1'b1), .S (S_n) ); end endgenerate endmodule

module generic_baseblocks_v2_1_carry_latch_or # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire I, output wire O ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign O = CIN | I; end else begin : USE_FPGA OR2L or2l_inst1 ( .O(O), .DI(CIN), .SRI(I) ); end endgenerate endmodule

module generic_baseblocks_v2_1_carry # ( parameter C_FAMILY = "virtex6" // FPGA Family. Current version: virtex6 or spartan6. ) ( input wire CIN, input wire S, input wire DI, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Instantiate or use RTL code ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL assign COUT = (CIN & S) | (DI & ~S); end else begin : USE_FPGA MUXCY and_inst ( .O (COUT), .CI (CIN), .DI (DI), .S (S) ); end endgenerate endmodule

module generic_baseblocks_v2_1_comparator_sel_mask # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, input wire [C_DATA_WIDTH-1:0] V, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {V, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = V; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) | ( ( ( b_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule

module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule