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module LUT1 ( output O , input I0 ) ;
parameter [ 1 : 0 ] INIT = 0 ;
assign O = I0 ? INIT [ 1 ] : INIT [ 0 ] ;
endmodule
module LUT2 ( output O , input I0 , I1 ) ;
parameter [ 3 : 0 ] INIT = 0 ;
wire [ 1 : 0 ] s1 = I1 ? INIT [ 3 : 2 ] : INIT [ 1 : 0 ] ;
assign O = I0 ? s1 [ 1 ] : s1 [ 0 ] ;
endmodule
module LUT3 ( output O , input I0 , I1 , I2 ) ;
parameter [ 7 : 0 ] INIT = 0 ;
wire [ 3 : 0 ] s2 = I2 ? INIT [ 7 : 4 ] : INIT [ 3 : 0 ] ;
wire [ 1 : 0 ] s1 = I1 ? s2 [ 3 : 2 ] : s2 [ 1 : 0 ] ;
assign O = I0 ? s1 [ 1 ] : s1 [ 0 ] ;
endmodule
module LUT4 ( output O , input I0 , I1 , I2 , I3 ) ;
parameter [ 15 : 0 ] INIT = 0 ;
wire [ 7 : 0 ] s3 = I3 ? INIT [ 15 : 8 ] : INIT [ 7 : 0 ] ;
wire [ 3 : 0 ] s2 = I2 ? s3 [ 7 : 4 ] : s3 [ 3 : 0 ] ;
wire [ 1 : 0 ] s1 = I1 ? s2 [ 3 : 2 ] : s2 [ 1 : 0 ] ;
assign O = I0 ? s1 [ 1 ] : s1 [ 0 ] ;
endmodule
module LUTFF ( input CLK , D , output reg O ) ;
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initial O = 1 'b0 ;
always @ ( posedge CLK ) begin
O < = D ;
end
endmodule
module FABULOUS_MUX2 ( input I0 , I1 , S0 , output O ) ;
assign O = S0 ? I1 : I0 ;
endmodule
module FABULOUS_MUX4 ( input I0 , I1 , I2 , I3 , S0 , S1 , output O ) ;
wire A0 = S0 ? I1 : I0 ;
wire A1 = S0 ? I3 : I2 ;
assign O = S1 ? A1 : A0 ;
endmodule
module FABULOUS_MUX8 ( input I0 , I1 , I2 , I3 , I4 , I5 , I6 , I7 , S0 , S1 , S2 , output O ) ;
wire A0 = S0 ? I1 : I0 ;
wire A1 = S0 ? I3 : I2 ;
wire A2 = S0 ? I5 : I4 ;
wire A3 = S0 ? I7 : I6 ;
wire B0 = S1 ? A1 : A0 ;
wire B1 = S1 ? A3 : A2 ;
assign O = S2 ? B1 : B0 ;
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endmodule
module FABULOUS_LC # (
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parameter K = 4 ,
parameter [ 2 * * K - 1 : 0 ] INIT = 0 ,
parameter DFF_ENABLE = 1 'b0
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) (
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input CLK ,
input [ K - 1 : 0 ] I ,
output O ,
output Q
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) ;
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wire f_wire ;
//LUT #(.K(K), .INIT(INIT)) lut_i(.I(I), .Q(f_wire));
generate
if ( K = = 1 ) begin
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LUT1 # ( . INIT ( INIT ) ) lut1 ( . O ( f_wire ) , . I0 ( I [ 0 ] ) ) ;
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end else
if ( K = = 2 ) begin
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LUT2 # ( . INIT ( INIT ) ) lut2 ( . O ( f_wire ) , . I0 ( I [ 0 ] ) , . I1 ( I [ 1 ] ) ) ;
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end else
if ( K = = 3 ) begin
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LUT3 # ( . INIT ( INIT ) ) lut3 ( . O ( f_wire ) , . I0 ( I [ 0 ] ) , . I1 ( I [ 1 ] ) , . I2 ( I [ 2 ] ) ) ;
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end else
if ( K = = 4 ) begin
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LUT4 # ( . INIT ( INIT ) ) lut4 ( . O ( f_wire ) , . I0 ( I [ 0 ] ) , . I1 ( I [ 1 ] ) , . I2 ( I [ 2 ] ) , . I3 ( I [ 3 ] ) ) ;
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end
endgenerate
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LUTFF dff_i ( . CLK ( CLK ) , . D ( f_wire ) , . Q ( Q ) ) ;
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assign O = f_wire ;
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endmodule
( * blackbox * )
module Global_Clock ( output CLK ) ;
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`ifndef SYNTHESIS
initial CLK = 0 ;
always # 10 CLK = ~ CLK ;
`endif
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endmodule
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( * blackbox , keep * )
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module InPass4_frame_config ( input CLK , output O0 , O1 , O2 , O3 ) ;
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endmodule
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( * blackbox , keep * )
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module OutPass4_frame_config ( input CLK , I0 , I1 , I2 , I3 ) ;
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endmodule
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( * keep * )
module IO_1_bidirectional_frame_config_pass ( input CLK , T , I , output Q , O , ( * iopad_external_pin * ) inout PAD ) ;
assign PAD = T ? 1 ' bz : I ;
assign O = PAD ;
reg Q_q ;
always @ ( posedge CLK ) Q_q < = O ;
assign Q = Q_q ;
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endmodule
module MULADD ( A7 , A6 , A5 , A4 , A3 , A2 , A1 , A0 , B7 , B6 , B5 , B4 , B3 , B2 , B1 , B0 , C19 , C18 , C17 , C16 , C15 , C14 , C13 , C12 , C11 , C10 , C9 , C8 , C7 , C6 , C5 , C4 , C3 , C2 , C1 , C0 , Q19 , Q18 , Q17 , Q16 , Q15 , Q14 , Q13 , Q12 , Q11 , Q10 , Q9 , Q8 , Q7 , Q6 , Q5 , Q4 , Q3 , Q2 , Q1 , Q0 , clr , CLK ) ;
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parameter A_reg = 1 'b0 ;
parameter B_reg = 1 'b0 ;
parameter C_reg = 1 'b0 ;
parameter ACC = 1 'b0 ;
parameter signExtension = 1 'b0 ;
parameter ACCout = 1 'b0 ;
//parameter NoConfigBits = 6;// has to be adjusted manually (we don't use an arithmetic parser for the value)
// IMPORTANT: this has to be in a dedicated line
input A7 ; // operand A
input A6 ;
input A5 ;
input A4 ;
input A3 ;
input A2 ;
input A1 ;
input A0 ;
input B7 ; // operand B
input B6 ;
input B5 ;
input B4 ;
input B3 ;
input B2 ;
input B1 ;
input B0 ;
input C19 ; // operand C
input C18 ;
input C17 ;
input C16 ;
input C15 ;
input C14 ;
input C13 ;
input C12 ;
input C11 ;
input C10 ;
input C9 ;
input C8 ;
input C7 ;
input C6 ;
input C5 ;
input C4 ;
input C3 ;
input C2 ;
input C1 ;
input C0 ;
output Q19 ; // result
output Q18 ;
output Q17 ;
output Q16 ;
output Q15 ;
output Q14 ;
output Q13 ;
output Q12 ;
output Q11 ;
output Q10 ;
output Q9 ;
output Q8 ;
output Q7 ;
output Q6 ;
output Q5 ;
output Q4 ;
output Q3 ;
output Q2 ;
output Q1 ;
output Q0 ;
input clr ;
input CLK ; // EXTERNAL // SHARED_PORT // ## the EXTERNAL keyword will send this sisgnal all the way to top and the //SHARED Allows multiple BELs using the same port (e.g. for exporting a clock to the top)
// GLOBAL all primitive pins that are connected to the switch matrix have to go before the GLOBAL label
wire [ 7 : 0 ] A ; // port A read data
wire [ 7 : 0 ] B ; // port B read data
wire [ 19 : 0 ] C ; // port B read data
reg [ 7 : 0 ] A_q ; // port A read data register
reg [ 7 : 0 ] B_q ; // port B read data register
reg [ 19 : 0 ] C_q ; // port B read data register
wire [ 7 : 0 ] OPA ; // port A
wire [ 7 : 0 ] OPB ; // port B
wire [ 19 : 0 ] OPC ; // port B
reg [ 19 : 0 ] ACC_data ; // accumulator register
wire [ 19 : 0 ] sum ; // port B read data register
wire [ 19 : 0 ] sum_in ; // port B read data register
wire [ 15 : 0 ] product ;
wire [ 19 : 0 ] product_extended ;
assign A = { A7 , A6 , A5 , A4 , A3 , A2 , A1 , A0 } ;
assign B = { B7 , B6 , B5 , B4 , B3 , B2 , B1 , B0 } ;
assign C = { C19 , C18 , C17 , C16 , C15 , C14 , C13 , C12 , C11 , C10 , C9 , C8 , C7 , C6 , C5 , C4 , C3 , C2 , C1 , C0 } ;
assign OPA = A_reg ? A_q : A ;
assign OPB = B_reg ? B_q : B ;
assign OPC = C_reg ? C_q : C ;
assign sum_in = ACC ? ACC_data : OPC ; // we can
assign product = OPA * OPB ;
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// The sign extension was not tested
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assign product_extended = signExtension ? { product [ 15 ] , product [ 15 ] , product [ 15 ] , product [ 15 ] , product } : { 4 'b0000 , product } ;
assign sum = product_extended + sum_in ;
assign Q19 = ACCout ? ACC_data [ 19 ] : sum [ 19 ] ;
assign Q18 = ACCout ? ACC_data [ 18 ] : sum [ 18 ] ;
assign Q17 = ACCout ? ACC_data [ 17 ] : sum [ 17 ] ;
assign Q16 = ACCout ? ACC_data [ 16 ] : sum [ 16 ] ;
assign Q15 = ACCout ? ACC_data [ 15 ] : sum [ 15 ] ;
assign Q14 = ACCout ? ACC_data [ 14 ] : sum [ 14 ] ;
assign Q13 = ACCout ? ACC_data [ 13 ] : sum [ 13 ] ;
assign Q12 = ACCout ? ACC_data [ 12 ] : sum [ 12 ] ;
assign Q11 = ACCout ? ACC_data [ 11 ] : sum [ 11 ] ;
assign Q10 = ACCout ? ACC_data [ 10 ] : sum [ 10 ] ;
assign Q9 = ACCout ? ACC_data [ 9 ] : sum [ 9 ] ;
assign Q8 = ACCout ? ACC_data [ 8 ] : sum [ 8 ] ;
assign Q7 = ACCout ? ACC_data [ 7 ] : sum [ 7 ] ;
assign Q6 = ACCout ? ACC_data [ 6 ] : sum [ 6 ] ;
assign Q5 = ACCout ? ACC_data [ 5 ] : sum [ 5 ] ;
assign Q4 = ACCout ? ACC_data [ 4 ] : sum [ 4 ] ;
assign Q3 = ACCout ? ACC_data [ 3 ] : sum [ 3 ] ;
assign Q2 = ACCout ? ACC_data [ 2 ] : sum [ 2 ] ;
assign Q1 = ACCout ? ACC_data [ 1 ] : sum [ 1 ] ;
assign Q0 = ACCout ? ACC_data [ 0 ] : sum [ 0 ] ;
always @ ( posedge CLK )
begin
A_q < = A ;
B_q < = B ;
C_q < = C ;
if ( clr = = 1 'b1 ) begin
ACC_data < = 20 'b00000000000000000000 ;
end else begin
ACC_data < = sum ;
end
end
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endmodule
module RegFile_32x4 ( D0 , D1 , D2 , D3 , W_ADR0 , W_ADR1 , W_ADR2 , W_ADR3 , W_ADR4 , W_en , AD0 , AD1 , AD2 , AD3 , A_ADR0 , A_ADR1 , A_ADR2 , A_ADR3 , A_ADR4 , BD0 , BD1 , BD2 , BD3 , B_ADR0 , B_ADR1 , B_ADR2 , B_ADR3 , B_ADR4 , CLK ) ;
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//parameter NoConfigBits = 2;// has to be adjusted manually (we don't use an arithmetic parser for the value)
parameter AD_reg = 1 'b0 ;
parameter BD_reg = 1 'b0 ;
// IMPORTANT: this has to be in a dedicated line
input D0 ; // Register File write port
input D1 ;
input D2 ;
input D3 ;
input W_ADR0 ;
input W_ADR1 ;
input W_ADR2 ;
input W_ADR3 ;
input W_ADR4 ;
input W_en ;
output AD0 ; // Register File read port A
output AD1 ;
output AD2 ;
output AD3 ;
input A_ADR0 ;
input A_ADR1 ;
input A_ADR2 ;
input A_ADR3 ;
input A_ADR4 ;
output BD0 ; //Register File read port B
output BD1 ;
output BD2 ;
output BD3 ;
input B_ADR0 ;
input B_ADR1 ;
input B_ADR2 ;
input B_ADR3 ;
input B_ADR4 ;
input CLK ; // EXTERNAL // SHARED_PORT // ## the EXTERNAL keyword will send this sisgnal all the way to top and the //SHARED Allows multiple BELs using the same port (e.g. for exporting a clock to the top)
// GLOBAL all primitive pins that are connected to the switch matrix have to go before the GLOBAL label
//type memtype is array (31 downto 0) of std_logic_vector(3 downto 0); // 32 entries of 4 bit
//signal mem : memtype := (others => (others => '0'));
reg [ 3 : 0 ] mem [ 31 : 0 ] ;
wire [ 4 : 0 ] W_ADR ; // write address
wire [ 4 : 0 ] A_ADR ; // port A read address
wire [ 4 : 0 ] B_ADR ; // port B read address
wire [ 3 : 0 ] D ; // write data
wire [ 3 : 0 ] AD ; // port A read data
wire [ 3 : 0 ] BD ; // port B read data
reg [ 3 : 0 ] AD_q ; // port A read data register
reg [ 3 : 0 ] BD_q ; // port B read data register
integer i ;
assign W_ADR = { W_ADR4 , W_ADR3 , W_ADR2 , W_ADR1 , W_ADR0 } ;
assign A_ADR = { A_ADR4 , A_ADR3 , A_ADR2 , A_ADR1 , A_ADR0 } ;
assign B_ADR = { B_ADR4 , B_ADR3 , B_ADR2 , B_ADR1 , B_ADR0 } ;
assign D = { D3 , D2 , D1 , D0 } ;
initial begin
for ( i = 0 ; i < 32 ; i = i + 1 ) begin
mem [ i ] = 4 'b0000 ;
end
end
always @ ( posedge CLK ) begin : P_write
if ( W_en = = 1 'b1 ) begin
mem [ W_ADR ] < = D ;
end
end
assign AD = mem [ A_ADR ] ;
assign BD = mem [ B_ADR ] ;
always @ ( posedge CLK ) begin
AD_q < = AD ;
BD_q < = BD ;
end
assign AD0 = AD_reg ? AD_q [ 0 ] : AD [ 0 ] ;
assign AD1 = AD_reg ? AD_q [ 1 ] : AD [ 1 ] ;
assign AD2 = AD_reg ? AD_q [ 2 ] : AD [ 2 ] ;
assign AD3 = AD_reg ? AD_q [ 3 ] : AD [ 3 ] ;
assign BD0 = BD_reg ? BD_q [ 0 ] : BD [ 0 ] ;
assign BD1 = BD_reg ? BD_q [ 1 ] : BD [ 1 ] ;
assign BD2 = BD_reg ? BD_q [ 2 ] : BD [ 2 ] ;
assign BD3 = BD_reg ? BD_q [ 3 ] : BD [ 3 ] ;
endmodule
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`ifdef EQUIV
`define COMPLEX_DFF
`endif
`ifdef COMPLEX_DFF
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module LUTFF_E (
output reg O ,
input CLK , E , D
) ;
initial O = 1 'b0 ;
always @ ( posedge CLK )
if ( E )
O < = D ;
endmodule
module LUTFF_SR (
output reg O ,
input CLK , R , D
) ;
initial O = 1 'b0 ;
always @ ( posedge CLK )
if ( R )
O < = 0 ;
else
O < = D ;
endmodule
module LUTFF_SS (
output reg O ,
input CLK , S , D
) ;
initial O = 1 'b0 ;
always @ ( posedge CLK )
if ( S )
O < = 1 ;
else
O < = D ;
endmodule
module LUTFF_ESR (
output reg O ,
input CLK , E , R , D
) ;
initial O = 1 'b0 ;
always @ ( posedge CLK )
if ( E ) begin
if ( R )
O < = 0 ;
else
O < = D ;
end
endmodule
module LUTFF_ESS (
output reg O ,
input CLK , E , S , D
) ;
initial O = 1 'b0 ;
always @ ( posedge CLK )
if ( E ) begin
if ( S )
O < = 1 ;
else
O < = D ;
end
endmodule
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`endif // COMPLEX_DFF