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© 조준동 2008 ECE C03 Lecture 121 Lecture 12 Introduction to VHDL Hai Zhou ECE 303 Advanced Digital Design Spring 2002.

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Presentation on theme: "© 조준동 2008 ECE C03 Lecture 121 Lecture 12 Introduction to VHDL Hai Zhou ECE 303 Advanced Digital Design Spring 2002."— Presentation transcript:

1 © 조준동 2008 ECE C03 Lecture 121 Lecture 12 Introduction to VHDL Hai Zhou ECE 303 Advanced Digital Design Spring 2002

2 © 조준동 2008 ECE C03 Lecture 122 Outline VHDL Language Basics Interface Architecture Body Process Signal Assignment and Delay Models Various Sequential Statements READING: Dewey 11.2, 11.3, 11.4, 11.5. 11.6, 15.1, 15.2, 18.2, 18.3, 18.4, 18.5 © 조준동 2008

3 ECE C03 Lecture 123 Modeling Digital Systems Digital system: Any digital circuit that processes or stores information in digital form: gates to functional units Model represents only relevant information and abstracts away irrelevant detail Model needed to: –Develop and specify requirements –Communicate understanding of a system to a user –Allow testing of design through simulation –Allow formal verification –Allow automated synthesis

4 © 조준동 2008 ECE C03 Lecture 124 What is VHDL (Very High Speed Integrated Circuits) VHSIC Hardware Description Language Used for two things –(1) Used to model digital systems, designs can then be SIMULATED A simulator runs a VHDL description computing the outputs of a modeled system –(2) Used as a language to enter designs into CAD tools, designs can then be SYNTHESIZED VHDL also provides a blackboard for designing digital systems An initial design is progressively expanded and refined Another popular hardware language is Verilog

5 © 조준동 2008 ECE C03 Lecture 125 Relationship between VHDL and hardware Model VHDL description Simulator Simulated / actual outputs Hardware

6 © 조준동 2008 ECE C03 Lecture 126 Example of VHDL Description VHDL Model of a 2input exclusive OR gate entity XOR2_OP is -- input output ports port (A, B : in BIT; Z : out BIT); -- Body architecture EX_DISJUNCTION of XOR_OP2 is begin Z <= A xor B; end EX_DISJUNCTION; Z A B

7 © 조준동 2008 ECE C03 Lecture 127 VHDL Entity Definitions A VHDL entity consists of two parts: –interface denoted by keyword “entity” – body denoted by keyword “architecture” Interface describes aspects visible outside Body describes how black box operates inside FORMAT: entity identifier is port (name: in / out / inout BIT/type); end identifier; -- lines beginning with two dashes are comments

8 © 조준동 2008 ECE C03 Lecture 128 VHDL Architecture Body Architecture body describes how entity operates Allows for different implementations Can have behavioral or structural or mixed representations FORMAT architecture EX_DISJUNCTION of XOR_OP2 is begin Z <= A xor B; end EX_DISJUNCTION;

9 © 조준동 2008 ECE C03 Lecture 129 Architecture Body Body is divided into two parts –Declarative part –Statement part architecture EX_DISJUNTION of XOR_OP2 is -- declarative part -- objects must be declared before they are used begin -- statement part Z <= A xor B; end EX_DISJUNCTION;

10 © 조준동 2008 ECE C03 Lecture 1210 Data Types in VHDL The type of a data object defines the set of values that object can assume and set of operations on those values –VHDL is a strongly typed language Four classes of objects –constants –variables –signals –files

11 © 조준동 2008 ECE C03 Lecture 1211 Constant Declaration The value of a constant cannot be changed FORMAT: constant identifier {, } : subtype [ := expression] EXAMPLES: constant number_of_bytes : integer := 4; constant prop_delay : time := 3nsec; constant e : real := 2.2172;

12 © 조준동 2008 ECE C03 Lecture 1212 Variable Declaration The value of a variable can be changed FORMAT variable identifier {,..} subtype [ := expression] EXAMPLES variable index: integer := 0; variable sum, average, largest : real; variable start, finish : time : = 0 nsec;

13 © 조준동 2008 ECE C03 Lecture 1213 Variable Assignment Statement Once a variable is declared, its value can be modified by an assignment statement FORMAT: [ label : ] name := expression; EXAMPLES: program_counter := 0; index := index + 1; Variable assignment different from signal assignment –A variable assignment immediately overviews variable with new value –A signal assignment schedules new value at later time

14 © 조준동 2008 ECE C03 Lecture 1214 Scalar Types Variable can only assign values of nominated type Default types –“integer”, “real”, “character,” “boolean”, “bit” User defined types –FORMAT: type small_int is range 0 to 255; Enumerated type: –FORMAT: type logiclevel is (unknown, low, driven, high);

15 © 조준동 2008 ECE C03 Lecture 1215 Expressions and Operators

16 © 조준동 2008 ECE C03 Lecture 1216 VHDL Modeling Concepts Semantics (meaning) is heavily based on SIMULATION A design is described as a set of interconnected modules A module could be another design (component) or could be described as a sequential program (process)

17 © 조준동 2008 ECE C03 Lecture 1217 A general VHDL design I1 I2 O1 IO1 Entity … is … End entity; component process 1process 2 concurrent assignment concurrent assignment I1 I2 O1 IO1 s1 s2 s3 s4 s5 s6 s7 s8s9 architecture … of … is... begin … end;

18 © 조준동 2008 ECE C03 Lecture 1218 VHDL Simulator start stop Init t = 0 more event get earliest event delta delay update signals advance time execute triggered processes during process execution, new events may be added

19 © 조준동 2008 ECE C03 Lecture 1219 Process Statements FORMAT PROCESS_LABEL: process -- declarative part declares functions, procedures, types, constants, variables, etc begin -- Statement part sequential statement; wait statement; -- eg. Wait for 1 ms; or wait on ALARM_A; sequential statement; … wait statement; end process; Flow of control

20 © 조준동 2008 ECE C03 Lecture 1220 Sequential Statements Sequential statements of various types are executed in sequence within each VHDL process Variable statement variable := expression; Signal Assignment If statement Case statement Loop statement Wait statement

21 © 조준동 2008 ECE C03 Lecture 1221 Variable and Sequential Signal Assignment Variable assignment –new values take effect immediately after execution variable LOGIC_A, LOGIC_B : BIT; LOGIC_A := ‘1’; LOGIC_B := LOGIC_A; Signal assignment –new values take effect after some delay (delta if not specified) signal LOGIC_A : BIT; LOGIC_A <= ‘0’; LOGIC_A <= ‘0’ after 1 sec; LOGIC_A <= ‘0’ after 1 sec, ‘1’ after 3.5 sec;

22 © 조준동 2008 ECE C03 Lecture 1222 Signal Declaration and Assignment Signal declaration: describes internal signal signal identifier {…} : subtype [ := expression] EXAMPLE: signal and_a, and_b : bit; Signal Assignment name <= value_expression [ after time_expression]; EXAMPLE y <= not or_a_b after 5 ns; This specifies that signal y is to take on a new value at a time 5 ns later statement execution. Difference from variable assignment: –which only assigns some values to a variable

23 © 조준동 2008 ECE C03 Lecture 1223 Concepts of Delays and Timing The time dimension in the signal assignment refers to simulation time in a discrete event simulation There is a simulation time clock When a signal assignment is executed, the delay specified is added to current simulation time to determine when new value is applied to signal –Schedules a transaction for the signal at that time input output

24 © 조준동 2008 ECE C03 Lecture 1224 Specifying Technology Information One predefined physical type in VHDL: TIME Units: fs (10** -15 seconds), ps (1000 fs), ns, us, ms, sec, min ( 60 sec), hr (60 min) User-defined physical types type CAPACITANCE is range 0 to INTEGER’HIGH units fF; -- Femtofarads pF = 1000 fF;-- Picofarads nF = 1000 pF;-- Nanofarads end units type VOLTAGE is range 0 to 2 ** 32 -1 units uV; -- Microvolt; mV = 1000 uV; V = 1000 mV; end units;

25 © 조준동 2008 ECE C03 Lecture 1225 Specifying Delays Inertial Delay Model –reflects physical inertia of physical systems –glitches of very small duration not reflected in outputs SIG_OUT <= not SIG_IN after 7 nsec --implicit SIG_OUT <= inertial ( not SIG_IN after 7 nsec ) Logic gates exhibit lowpass filtering SIG_IN SIG_OUT 2ns 9 ns19 ns 3 ns 10ns

26 © 조준동 2008 ECE C03 Lecture 1226 Transport Delays Under this model, ALL input signal changes are reflected at the output SIG_OUT <= transport not SIG_IN after 7 ns; SIG_IN SIG_OUT 2ns 9 ns19 ns 3 ns 10ns 30 ns

27 © 조준동 2008 ECE C03 Lecture 1227 If Statement FORMAT if boolean_expression then {sequential statement} elsif boolean_expression then {sequential statement} else {sequential statement} endif; EXAMPLE if sel=0 then result <= input_0; -- executed if sel = 0 else result <= input_1; -- executed if sel = 1 endif ;

28 © 조준동 2008 ECE C03 Lecture 1228 Case Statement EXAMPLE of an ALU operation: case func is when pass1 => result := operand1; when pass2 => result := operand2; when add => result := operand1 + operand2; when subtract => result := operand1 - operand2; end case;

29 © 조준동 2008 ECE C03 Lecture 1229 Loop Statements While condition loop {sequential statements} end loop; for identifier in range loop {sequential statements} end loop; while index > 0 loop index := index -1; end loop; for count in 0 to 127 loop count_out <= count; wait for 5 ns; end loop; for i in 1 to 10 loop count := count + 1; end loop;

30 © 조준동 2008 ECE C03 Lecture 1230 Wait Statement A wait statement specifies how a process responds to changes in signal values. wait on signal_name wait until boolean_expression wait for time_expression Example on right shows process sensitivity list EXAMPLE: SAME AS: half_add: process is begin sum <= a xor b after T_pd; carry <= a and b after T_pd; wait on a, b; end process; half_add: process (a,b) is begin sum <= a xor b after T_pd; carry <= a and b after T_pd; end process;

31 © 조준동 2008 ECE C03 Lecture 1231 Example of Architecture Body(AND_OR_INVERT) architecture primitive of and_or_inv is signal and_a, and_b, or_a_b : bit; begin and_gate_a : process (a1,a2) is begin and_a <= a1 and a2; end process and_gate_a; and_gate_b : process (b1,b2) is begin and_b <= b1 and b2; end process and_gate_b; or_gate: process (and_a, and_b) is begin or_a_b <= and_a or and_b; end process or_gate; inv : process (or_a_b) is begin y <= not or_a_b; end process inv; end architecture primitive; a1 a2 b1 b2 y

32 © 조준동 2008 ECE C03 Lecture 1232 Process Declaration of Clock Generator Clock_gen: process (clk) is begin if clk = ‘0’ then clk <= ‘1’ after T_pw, ‘0’ after 2*T_pw; endif; end process clock_gen; T_pw 2*T_pw

33 © 조준동 2008 ECE C03 Lecture 1233 Process Generator for Multiplexer a b sel z mux: process (a, b, sel) is begin case sel is when ‘0’ => z <= a after prop_delay; when ‘1’ => z <= b after prop_delay; end process mux;

34 © 조준동 2008 ECE C03 Lecture 1234 Summary VHDL Language Basics Interface Architecture Body Process Signal Assignment and Delay Models Various Sequential Statements NEXT LECTURE: VHDL Structural Description READING: Dewey 12.1, 12.2, 12.3, 12.4, 13.1, 13.2, 13.3. 13.4, 13.6, 13.7. 13.8

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