EE 3563 VHSIC Hardware Description Language Required Reading

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EE 3563 VHSIC Hardware Description Language ¨ Required Reading: – These Slides – VHDL

EE 3563 VHSIC Hardware Description Language ¨ Required Reading: – These Slides – VHDL Tutorial ¨ Very High Speed Integrated Circuit (VHSIC) ¨ VHSIC Hardware Description Language (VHDL) Fall 2004 EE 3563 Digital Systems Design

Fall 2004 EE 3563 Digital Systems Design

Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL ¨ Used to model a digital system at numerous different levels

EE 3563 VHDL ¨ Used to model a digital system at numerous different levels – Algorithmic level to gate level to system level ¨ Can express concurrent or sequential behavior, with or without timing ¨ Models written in this language can be verified with simulation ¨ The language is very complex, but we can focus on a small part and still make use of it ¨ VHDL was constructed in the early 80’s as a Do. D requirement – Many companies were making electronic components for Do. D and needed standardization in order to share designs – VHDL 7. 2, was released in 1985 – IEEE made it an industry standard in 1987 – Book I have is based on 1993 standard Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL ¨ ¨ Exchange medium between chip vendors and CAD tool users

EE 3563 VHDL ¨ ¨ Exchange medium between chip vendors and CAD tool users Communication medium between CAD and CAE tools – – ¨ ¨ ¨ ¨ Computer Automated Design, Computer Aided Engineering Schematic can be converted to VHDL for simulation Supports a hierarchy – one component can become a sub-component of a larger system Not technology specific – can support many technologies Synchronous and Asynchronous models Supports finite state machines, algorithms, & boolean equations Publicly available, not proprietary IEEE and ANSI standard Three basic different description styles Wide range of abstraction levels, though not down to transistor level Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL ¨ No limitations on design size imposed by VHDL ¨ Propagation

EE 3563 VHDL ¨ No limitations on design size imposed by VHDL ¨ Propagation delays, setup and hold timing, timing constraints, and spike detection can all be modeled ¨ Tools that use VHDL code can work with designs from multiple vendors since the language is a standard ¨ Behavioral models that conform to certain synthesis description styles are able to be synthesized – The gate design can be generated from the behavior ¨ There are other features, but this should give you an idea Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Overview ¨ A hardware abstraction is called an entity ¨ One

EE 3563 VHDL Overview ¨ A hardware abstraction is called an entity ¨ One entity, X, used inside another entity, Y, is called a component ¨ VHDL has 5 primary constructs: – – – Entity declaration Architecture body Configuration declaration Package body ¨ An entity has an entity declaration and at least one architecture body ¨ The entity declaration describes the external view – An “AND” gate would have 2 inputs and 1 output – more later Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Overview ¨ The architecture body contains the internal description – Could

EE 3563 VHDL Overview ¨ The architecture body contains the internal description – Could be interconnected components representing the structure – Could be statements that represent the behavior – Each of these styles can be in a separate architecture body or mixed ¨ A configuration declaration is used to specify the binding of ¨ ¨ one architecture body from the possibly multiple other architectures It may also specify the bindings of components used in the architecture body to other entities An entity may have multiple configurations A package declaration is a set of related declarations A package body contains the definitions associated with the declarations – Ex: A course syllabus is the declaration, the actual course is the body Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Overview ¨ Once an entity is modeled, it must be validated

EE 3563 VHDL Overview ¨ Once an entity is modeled, it must be validated by VHDL ¨ ¨ software which includes an analyzer and a simulator The analyzer performs semantic checks and validates the syntax Then it compiles the VHDL code into a library The simulator reads its compiled description from the design library and then simulates the design It performs 3 steps – Elaboration – Initialization – Simulation ¨ NOTE: VHDL is case insensitive, so AND, and, An. D are the same Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ The entity declaration specifies the name of the entity

EE 3563 VHDL Example ¨ The entity declaration specifies the name of the entity and it’s input/output ports ¨ Ports are the signals that interface into and out of the entity ¨ Here is a half adder (why is it only a half adder? ) ¨ The name is: HALF_ADDER ¨ 4 ports: 2 input, 2 output ¨ They are of type BIT which means they can have one of two different values, 0 or 1 – The double dash indicates a comment Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ The schematic is just for our reference, so far,

EE 3563 VHDL Example ¨ The schematic is just for our reference, so far, the only VHDL is the entity declaration ¨ It says NOTHING about how HALF_ADDER works, its functionality or behavior ¨ It ONLY specifies inputs and outputs – I made it bigger so you can see there is nothing else there ¨ Three types of modeling: structural, dataflow, behavioral Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ Structural modeling of HALF_ADDER – this works in conjunction

EE 3563 VHDL Example ¨ Structural modeling of HALF_ADDER – this works in conjunction with the declaration – an entity is described as a set of interconnected components ¨ The architecture body is composed of two parts: – declarative part (after the keyword begin) – the statement part (after the keyword begin) ¨ In our case, two components are declared (XOR 2, AND 2) – they specify the interface of components used in the architecture body – They are either user-specified in their own entity declaration and architecture body or are used from the pre-defined library ¨ They are instantiated in the statement part of the architecture body Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ The statement part of HALF_ADDER is inside the begin/end

EE 3563 VHDL Example ¨ The statement part of HALF_ADDER is inside the begin/end ¨ The X 1 statement creates an instance of XOR 2 – Many Dodge Vipers are made, but the one I own (1/100 th scale) is a specific instance of a Viper ¨ The signals in the port map are associated with the signals of a component using positional association – (the X input for XOR 2 is mapped to the A input of HALF_ADDER) Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ Dataflow modeling of HALF_ADDER ¨ The flow of data

EE 3563 VHDL Example ¨ Dataflow modeling of HALF_ADDER ¨ The flow of data is expressed using concurrent signal assignment statements ¨ Each assignment statement is executed at the same time (concurrently) ¨ Order is NOT important ¨ SIDE NOTE: – You may wonder how a computer simulation can do this? It can’t. – However, we are talking about two different types of time. – In real-time, the computer can only perform a single task at any given point, but here we mean the statements are executed in concurrently in simulated time. Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ Here is the dataflow model of HALF_ADDER architecture HA_CONCURRENT

EE 3563 VHDL Example ¨ Here is the dataflow model of HALF_ADDER architecture HA_CONCURRENT of HALF_ADDER is begin SUM <= A xor B after 8 ns; CARRY <= A and B after 4 ns; end HA_CONCURRENT; ¨ The name is HA_CONCURRENT ¨ The signals SUM & CARRY get assigned (<= ) values ¨ Note the after statement, it specifies when the signal (in simulated time) gets its new value ¨ If no after statement is given, then the default delay is used ¨ The default delay (0 ns) is called the delta delay and is a number infinitesimally above zero Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ Behavioral style of modeling specifies the functionality of an

EE 3563 VHDL Example ¨ Behavioral style of modeling specifies the functionality of an entity with sequential statements ¨ Order IS important, because one statement is executed (in simulated time) one right after the other ¨ The statements are specified inside a process statement ¨ They only specify the functionality of an entity, NOT its structure – Structure of XOR could be either of these or some other design – Example, could be a T-gate implementation Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example ¨ Here is the behavior model of HALF_ADDER architecture HA_CONCURRENT

EE 3563 VHDL Example ¨ Here is the behavior model of HALF_ADDER architecture HA_CONCURRENT of HALF_ADDER is begin process (A, B) begin SUM <= A xor B; CARRY <= A and B; end process; end HA_CONCURRENT; ¨ Whenever there is an event on A or B, the process is executed ¨ The sequential statements are executed regardless of whether an event occurs on the right hand side of their expression – In this case, an event must occur on A or B to get here, but this is not the general case Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Now we will step through another

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Now we will step through another example ¨ This is a 2 -to-4 Decoder circuit, note the entity declaration ¨ BIT_VECTOR is another data type (it is an array of bits) ¨ Quiz: Entity name? # Inputs? # Outputs? Data types? ¨ How many components? How many instantiations? Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Structural model of 2 -to-4 Decoder

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Structural model of 2 -to-4 Decoder Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Dataflow model of 2 -to-4 Decoder

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Dataflow model of 2 -to-4 Decoder ¨ Note the signals: ABAR, BBAR of type BIT ¨ Concurrent or sequential? ¨ What time delay is used? Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Behavioral model of 2 -to-4 Decoder

EE 3563 VHDL Example: 2 -to-4 Decoder ¨ Behavioral model of 2 -to-4 Decoder ¨ Concurrent or sequential? ¨ Note the variables ABAR, BBAR of type BIT – Variables are different than signals in that they are assigned a value instantaneously ( : = ) ¨ The process statement also has declarative & statement parts Variables are declared, statements are within the begin/end process statements Scope is limited to process in which variable is declared Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Example: Flip-Flop entity LS_DFF is -- declaration for level-sensitive flip-flop port(Q:

EE 3563 VHDL Example: Flip-Flop entity LS_DFF is -- declaration for level-sensitive flip-flop port(Q: out BIT; D, CLK: in BIT); end LS_DFF architecture LS_DFF_BEH of LS_DFF is begin process(D, CLK) begin if CLK=‘ 1’ then -- if CLK is one, D is assigned to Q Q <= D end if; end process; end LS_DFF_BEH; Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL Mixed Modeling ¨ The three types of modeling can be combined

EE 3563 VHDL Mixed Modeling ¨ The three types of modeling can be combined within an architecture body – component instantiation – structural – concurrent signal assignments – dataflow – process statements – behavior ¨ This is called the mixed style of modeling Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL ¨ FULL ADDER Fall 2004 EE 3563 Digital Systems Design

EE 3563 VHDL ¨ FULL ADDER Fall 2004 EE 3563 Digital Systems Design