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VHDL Examples

VHDL Examples. Subra Ganesan Reference: Professor Haskell’s Notes, Digital design with VHDL book by Vranesic. n-line 2-to-1 Multiplexer. n-line 2 x 1 MUX. a(n-1:0). y(n-1:0). b(n-1:0). sel y 0 a 1 b. sel. a(n-1:0). n-line. 2 x 1. y(n-1:0).

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VHDL Examples

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  1. VHDL Examples Subra Ganesan Reference: Professor Haskell’s Notes, Digital design with VHDL book by Vranesic

  2. n-line 2-to-1 Multiplexer n-line 2 x 1 MUX a(n-1:0) y(n-1:0) b(n-1:0) sel y 0 a 1 b sel

  3. a(n-1:0) n-line 2 x 1 y(n-1:0) MUX b(n-1:0) sel An n-line 2 x 1 MUX library IEEE; use IEEE.std_logic_1164.all; entity mux2g is generic (width:positive); port ( a: in STD_LOGIC_VECTOR(width-1 downto 0); b: in STD_LOGIC_VECTOR(width-1 downto 0); sel: in STD_LOGIC; y: out STD_LOGIC_VECTOR(width-1 downto 0) ); end mux2g;

  4. generic statement defines width of bus Entity Each entity must begin with these library and use statements library IEEE; use IEEE.std_logic_1164.all; entity mux2g is generic (width:positive); port ( a: in STD_LOGIC_VECTOR(width-1 downto 0); b: in STD_LOGIC_VECTOR(width-1 downto 0); sel: in STD_LOGIC; y: out STD_LOGIC_VECTOR(width-1 downto 0) ); end mux2g; port statement defines inputs and outputs

  5. Entity Mode: in or out library IEEE; use IEEE.std_logic_1164.all; entity mux2g is generic (width:positive); port ( a: in STD_LOGIC_VECTOR(width-1 downto 0); b: in STD_LOGIC_VECTOR(width-1 downto 0); sel: in STD_LOGIC; y: out STD_LOGIC_VECTOR(width-1 downto 0) ); end mux2g; Data type: STD_LOGIC, STD_LOGIC_VECTOR(width-1 downto 0);

  6. Standard Logic library IEEE; use IEEE.std_logic_1164.all; type std_ulogic is ( ‘U’, -- Uninitialized ‘X’ -- Forcing unknown ‘0’ -- Forcing zero ‘1’ -- Forcing one ‘Z’ -- High impedance ‘W’ -- Weak unknown ‘L’ -- Weak zero ‘H’ -- Weak one ‘-’); -- Don’t care

  7. Standard Logic Type std_ulogic is unresolved. Resolved signals provide a mechanism for handling the problem of multiple output signals connected to one signal. subtype std_logic is resolved std_ulogic;

  8. a(n-1:0) n-line 2 x 1 y(n-1:0) MUX b(n-1:0) sel Architecture architecture mux2g_arch of mux2g is begin mux2_1: process(a, b, sel) begin if sel = '0' then y <= a; else y <= b; endif; end process mux2_1; end mux2g_arch; Note: <= is signal assignment

  9. Architecture entity name process sensitivity list architecture mux2g_arch of mux2g is begin mux2_1: process(a, b, sel) begin if sel = '0' then y <= a; else y <= b; endif; end process mux2_1; end mux2g_arch; Sequential statements (if…then…else) must be in a process Note begin…end in process Note begin…end in architecture

  10. Top-level design for Lab 1 library IEEE; use IEEE.STD_LOGIC_1164.all; use IEEE.std_logic_unsigned.all; entity Lab1 is port( SW : in STD_LOGIC_VECTOR(7 downto 0); BTN0 : in STD_LOGIC; LD : out STD_LOGIC_VECTOR(3 downto 0) ); end Lab1;

  11. architecture Lab1_arch of Lab1 is component mux2g generic( width : POSITIVE); port( a : in std_logic_vector((width-1) downto 0); b : in std_logic_vector((width-1) downto 0); sel : in std_logic; y : out std_logic_vector((width-1) downto 0)); end component; constant bus_width: integer := 4; begin mux2: mux2g generic map(width => bus_width) port map (a => SW(7 downto 4),b => SW(3 downto 0), sel => BTN0, y => LD); end Lab1_arch;

  12. Sel y “00” a “01” b “10” c “11” d Example of case statement architecture mux4g_arch of mux4g is begin process (sel, a, b, c, d) begin case sel is when "00" => y <= a; when "01" => y <= b; when "10" => y <= c; when others => y <= d; end case; end process; end mux4g_arch; Note implies operator => Must include ALL possibilities in case statement

  13. 7-Segment Display seg7dec D(3:0) AtoG(6:0) Truth table D a b c d e f g 8 1 1 1 1 1 1 1 9 1 1 1 1 0 1 1 A 1 1 1 0 1 1 1 b 0 0 1 1 1 1 1 C 1 0 0 1 1 1 0 d 0 1 1 1 1 0 1 E 1 0 0 1 1 1 1 F 1 0 0 0 1 1 1 D a b c d e f g 0 1 1 1 1 1 1 0 1 0 1 1 0 0 0 0 2 1 1 0 1 1 0 1 3 1 1 1 1 0 0 1 4 0 1 1 0 0 1 1 5 1 0 1 1 0 1 1 6 1 0 1 1 1 1 1 7 1 1 1 0 0 0 0

  14. 7-Segment Display Verilog case(D) 0: AtoG = 7'b1111110; 1: AtoG = 7'b0110000; 2: AtoG = 7'b1101101; 3: AtoG = 7'b1111001; 4: AtoG = 7'b0110011; 5: AtoG = 7'b1011011; 6: AtoG = 7'b1011111; 7: AtoG = 7'b1110000; 8: AtoG = 7'b1111111; 9: AtoG = 7'b1111011; 'hA: AtoG = 7'b1110111; 'hb: AtoG = 7'b0011111; 'hC: AtoG = 7'b1001110; 'hd: AtoG = 7'b0111101; 'hE: AtoG = 7'b1001111; 'hF: AtoG = 7'b1000111; default: AtoG = 7'b1111110; // 0 endcase Behavior seg7dec D(3:0) AtoG(6:0)

  15. 7-Segment Display VHDL -- seg7dec with digit select ssg <= "1001111" when "0001", --1 "0010010" when "0010", --2 "0000110" when "0011", --3 "1001100" when "0100", --4 "0100100" when "0101", --5 "0100000" when "0110", --6 "0001111" when "0111", --7 "0000000" when "1000", --8 "0000100" when "1001", --9 "0001000" when "1010", --A "1100000" when "1011", --b "0110001" when "1100", --C "1000010" when "1101", --d "0110000" when "1110", --E "0111000" when "1111", --F "0000001" when others; --0 Behavior (Active LOW) AtoG seg7dec digit(3:0) sseg(6:0)

  16. Comparators Recall that an XNOR gate can be used as an equality detector XNOR X if X = Y then Z <= '1'; else Z <= '0'; end if; Z Y Z = !(X $ Y) Z = X xnor Y Z = ~(X @ Y) X Y Z 0 0 1 0 1 0 1 0 0 1 1 1

  17. 4-Bit Equality Comparator A: in STD_LOGIC_VECTOR(3 downto 0); B: in STD_LOGIC_VECTOR(3 downto 0); A_EQ_B: out STD_LOGIC;

  18. library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; entity eqdet4 is Port ( A : in std_logic_vector(3 downto 0); B : in std_logic_vector(3 downto 0); A_EQ_B : out std_logic); end eqdet4; architecture Behavioral of eqdet4 is signal C: std_logic_vector(3 downto 0); begin C <= A xnor B; A_EQ_B <= C(0) and C(1) and C(2) and C(3); end Behavioral;

  19. comp A_EQ_B A(n-1:0) A_GT_B A_LT_B B(n-1:0) A_UGT_B A_ULT_B Comparators A, B signed A, B unsigned Signed: 2's complement signed numbers

  20. -- Comparator for unsigned and signed numbers library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_arith.all; use IEEE.std_logic_unsigned.all; entity comp is generic(width:positive); port ( A: in STD_LOGIC_VECTOR(width-1 downto 0); B: in STD_LOGIC_VECTOR(width-1 downto 0); A_EQ_B: out STD_LOGIC; A_GT_B: out STD_LOGIC; A_LT_B: out STD_LOGIC; A_ULT_B: out STD_LOGIC; A_UGT_B: out STD_LOGIC ); end comp; comp A_EQ_B A(n-1:0) A_GT_B A_LT_B B(n-1:0) A_UGT_B A_ULT_B

  21. architecture comp_arch of comp is begin CMP: process(A,B) variable AVS, BVS: signed(width-1 downto 0); begin for i in 0 to width-1 loop AVS(i) := A(i); BVS(i) := B(i); end loop; A_EQ_B <= '0'; A_GT_B <= '0'; A_LT_B <= '0'; A_ULT_B <= '0'; A_UGT_B <= '0'; if (A = B) then A_EQ_B <= '1'; end if; if (AVS > BVS) then A_GT_B <= '1'; end if; if (AVS < BVS) then A_LT_B <= '1'; end if; if (A > B) then A_UGT_B <= '1'; end if; if (A < B) then A_ULT_B <= '1'; end if; end process CMP; end comp_arch; comp A_EQ_B A(n-1:0) A_GT_B A_LT_B B(n-1:0) A_UGT_B A_ULT_B Note: All outputs must be assigned some value. The last signal assignment in a process is the value assigned

  22. 4-Bit Comparator

  23. Full Adder Truth table Ci Si Ai Ci+1 Bi Behavior Ci+1:Si = Ci + Ai + Bi

  24. Full Adder Block Diagram

  25. 4-Bit Adder C 1 1 1 0 0:A 0 1 1 0 1 0:B 0 0 1 1 1 C4:S 1 0 1 0 0

  26. library IEEE; use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_unsigned.all; entity adder4 is port( A : in STD_LOGIC_VECTOR(3 downto 0); B : in STD_LOGIC_VECTOR(3 downto 0); carry : out STD_LOGIC; S : out STD_LOGIC_VECTOR(3 downto 0) ); end adder4; architecture adder4 of adder4 is begin process(A,B) variable temp: STD_LOGIC_VECTOR(4 downto 0); begin temp := ('0' & A) + ('0' & B); S <= temp(3 downto 0); carry <= temp(4); end process; end adder4;

  27. 4-Bit Adder

  28. 3-to-8 Decoder A: in STD_LOGIC_VECTOR(2 downto 0); Y: out STD_LOGIC_VECTOR(0 to 7); Behavior for i in 0 to 7 loop if(i = conv_integer(A)) then Y(i) <= ‘1’; else Y(i) <= ‘0’; end if; end loop;

  29. library IEEE; use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_arith.all; use IEEE.STD_LOGIC_unsigned.all; entity decode38 is port( A : in STD_LOGIC_VECTOR(2 downto 0); Y : out STD_LOGIC_VECTOR(0 to 7) ); end decode38; architecture decode38 of decode38 is begin process(A) variable j: integer; begin j := conv_integer(A); for i in 0 to 7 loop if(i = j) then Y(i) <= '1'; else Y(i) <= '0'; end if; end loop; end process; end decode38; 3-to-8 Decoder

  30. Shifters Shift right Shift left Arithmetic shift right

  31. shift4.vhd library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity shifter is generic(width:positive := 4); port ( D: in STD_LOGIC_VECTOR(width-1 downto 0); s: in STD_LOGIC_VECTOR(1 downto 0); Y: out STD_LOGIC_VECTOR(width-1 downto 0) ); end shifter;

  32. architecture shifter_arch of shifter is begin shift_1: process(D, s) begin case s is when "00" => -- no shift Y <= D; when "01" => -- U2/ Y <= '0' & D(width-1 downto 1); when "10" => -- 2* Y <= D(width-2 downto 0) & '0'; when "11" => -- 2/ Y <= D(width-1) & D(width-1 downto 1); whenothers => -- no shift Y <= D; end case; end process shift_1; end shifter_arch;

  33. Code Converters • Gray Code Converter • Binary-to-BCD Converter

  34. Gray Code Definition: An ordering of 2n binary numbers such that only one bit changes from one entry to the next. Binary coding {0...7}: {000, 001, 010, 011, 100, 101, 110, 111} Gray coding {0...7}: {000, 001, 011, 010, 110, 111, 101, 100} Not unique One method for generating a Gray code sequence: Start with all bits zero and successively flip the right-most bit that produces a new string.

  35. Binary - Gray Code Conversions Gray code: G(i), i = n – 1 downto 0 Binary code: B(i), i = n – 1 downto 0 Binary coding {0...7}: {000, 001, 010, 011, 100, 101, 110, 111} Gray coding {0...7}: {000, 001, 011, 010, 110, 111, 101, 100} Convert Binary to Gray: Copy the most significant bit. For each smaller i G(i) = B(i+1) xor B(i) Convert Gray to Binary: Copy the most significant bit. For each smaller i B(i) = B(i+1) xor G(i)

  36. bin2gray.vhd library IEEE; use IEEE.STD_LOGIC_1164.all; entity bin2gray is generic(width:positive := 3); port( B : in STD_LOGIC_VECTOR(width-1 downto 0); G : out STD_LOGIC_VECTOR(width-1 downto 0) ); end bin2gray; architecture bin2gray of bin2gray is begin process(B) begin G(width-1) <= B(width-1); for i in width-2 downto 0 loop G(i) <= B(i+1) xor B(i); end loop; end process; end bin2gray;

  37. library IEEE; use IEEE.STD_LOGIC_1164.all; entity gray2bin is generic(width:positive := 3); port( G : in STD_LOGIC_VECTOR(width-1 downto 0); B : out STD_LOGIC_VECTOR(width-1 downto 0) ); end gray2bin; architecture gray2bin of gray2bin is begin process(G) variable BV: STD_LOGIC_VECTOR(width-1 downto 0); begin BV(width-1) := G(width-1); for i in width-2 downto 0 loop BV(i) := BV(i+1) xor G(i); end loop; B <= BV; end process; end gray2bin; gray2bin.vhd

  38. Binary-to-BCD Conversion • Shift and add 3 algorithm • RTL solution • Behavioral solution

  39. Shift and Add-3 Algorithm 11. Shift the binary number left one bit. 22. If 8 shifts have taken place, the BCD number is in the Hundreds, Tens, and Units column. 33. If the binary value in any of the BCD columns is 5 or greater, add 3 to that value in that BCD column. 44. Go to 1.

  40. Steps to convert an 8-bit binary number to BCD

  41. Truth table for Add-3 Module A3 A2 A1 A0 C S3 S2 S1 S0

  42. Binary-to-BCD Converter RTL Solution

  43. Binary-to-BCD Converter: Behavioral Solution -- Title: Binary-to-BCD Converter library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity binbcd is port ( B: in STD_LOGIC_VECTOR (7 downto 0); P: out STD_LOGIC_VECTOR (9 downto 0) ); end binbcd;

  44. architecture binbcd_arch of binbcd is begin bcd1: process(B) variable z: STD_LOGIC_VECTOR (17 downto 0); begin for i in 0 to 17 loop z(i) := '0'; end loop; z(10 downto 3) := B; for i in 0 to 4 loop if z(11 downto 8) > 4 then z(11 downto 8) := z(11 downto 8) + 3; end if; if z(15 downto 12) > 4 then z(15 downto 12) := z(15 downto 12) + 3; end if; z(17 downto 1) := z(16 downto 0); end loop; P <= z(17 downto 8); end process bcd1; end binbcd_arch;

  45. 16-bit Binary-to-BCD Converter

  46. Verilog binbcd module binbcd(B,P); input [15:0] B; output [15:0] P; reg [15:0] P; reg [31:0] z; integer i;

  47. always @(B) begin for(i = 0; i <= 31; i = i+1) z[i] = 0; z[18:3] = B; for(i = 0; i <= 12; i = i+1) begin if(z[19:16] > 4) z[19:16] = z[19:16] + 3; if(z[23:20] > 4) z[23:20] = z[23:20] + 3; if(z[27:24] > 4) z[27:24] = z[27:24] + 3; if(z[31:28] > 4) z[31:28] = z[31:28] + 3; z[31:1] = z[30:0]; end P = z[31:16]; end endmodule

  48. Arithmetic Logic Units • ALU1 • Shifting, Increment and Decrement Instructions • ALU2 • Arithmetic and Logic Instructions • ALU3 • Comparators

  49. ALU1 Shifting, Increment and Decrement Instructions

  50. alu1.vhd library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity alu1 is generic(width:positive); port ( a: in STD_LOGIC_VECTOR(width-1 downto 0); sel: in STD_LOGIC_VECTOR(2 downto 0); y: out STD_LOGIC_VECTOR(width-1 downto 0) ); end alu1;

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