1. VHDL Structured Logic Design School of Electrical Engineering University of Belgrade Department of Computer Engineering Ivan Dugic idugic@verat.net Veljko Milutinovic vm@etf.bg.ac.yu idugic@verat.netvm@etf.bg.ac.yuidugic@verat.netvm@etf.bg.ac.yu

2. Ivan Dugic idugic@verat.net 2/29 Table of contents  HDL Introduction  Structured Design Concepts  Basic Features of VHDL  Design Process Highlights

3. Ivan Dugic idugic@verat.net 3/29 HDL Introduction

4. Ivan Dugic idugic@verat.net 4/29 Modern chip design aspects  Modern chips became too complex  The number of transistors in a modern chip is over a 100 M  Transistor count per chip and chip speed rise up to 50% per year  Estimated time needed for manual implementation (100 M transistor, 10 sec/transistor) – 135.5 years!!! HDL Introduction

5. Ivan Dugic idugic@verat.net 5/29 Modern ASIC design approach  ASIC – Application Specific Integrated Circuit  Modeling system should be designed and described in the highest abstraction level possible  Simulation and testing at high abstraction level  Conversion of the modeled system into the low abstraction level model (gate, circuit, silicon level) using sophisticated synthesis tools  Key point – CAD (Computer Aided Design) HDL Introduction

6. Ivan Dugic idugic@verat.net 6/29 Modern ASIC design approach  HDLs (Hardware Description Languages) are used for system description at the high abstraction level HDL Introduction Design DescriptionSimulation & Testing Gate Level Model Conversion RTL Model HIGH ABSTRACTION LEVEL LOW ABSTRACTION LEVEL

7. Ivan Dugic idugic@verat.net 7/29 VHDL  VHDL - VHSIC Hardware Description Language  VHSIC - Very High Speed Integrated Circuit  Development of VHDL began in 1983, sponsored by Department of defense, further developed by the IEEE and released as IEEE Standard 1076 in 1987  Today it is De facto industry standard for hardware description languages HDL Introduction

8. Ivan Dugic idugic@verat.net 8/29 Structural Design Concepts

9. Ivan Dugic idugic@verat.net 9/29 The abstraction hierarchy  The abstraction hierarchy can be expressed in two domains: structural domain, behavioral domain  Structural domain – component model is described in terms of an interconnection of more primitive components  Behavioral domain – component model is described by defining its input/output response  VHDL is used for both structural and behavioral description  Six abstraction hierarchy levels of detail commonly used in design: silicon, circuit, gate, register, chip and system Structural Design Concepts

10. Ivan Dugic idugic@verat.net 10/29 Design process  The design cycle consists of a series of transformations, synthesis steps: (1) Transformation from English to an algorithmic representation, natural language synthesis (2) Translation from an algorithmic representation to a data flow representation, algorithmic synthesis (3) Translation from data flow representation to a structural logic gate representation, logic synthesis (4) Translation from logic gate to layout and circuit representation, layout synthesis Structural Design Concepts

11. Ivan Dugic idugic@verat.net 11/29 Design process  The design cycle steps can be carried out automatically in all stages except the first that is currently an active area of research  VHDL tools are used for algorithmic synthesis Structural Design Concepts

12. Ivan Dugic idugic@verat.net 12/29 Design tools  Editors – textual (circuit level – SPICE gate, register, chip – VHDL) or graphic (used at all levels)  Simulators – stochastic (system level) or deterministic (all levels above the silicon level)  Checkers and Analyzers – employed at all levels, used for example (1) to insure that the circuit layout can be fabricated reliably (rule checkers), (2) to check for the longest path through a logic circuit or system (timing analyzers)  Synthesizers and Optimizers – improving a form of the design representation Structural Design Concepts

13. Ivan Dugic idugic@verat.net 13/29 Basic Features of VHDL

14. Ivan Dugic idugic@verat.net 14/29 Design entities  In VHDL a logic circuit is represented as a design entity  A design entity consists of two different VHDL types of description: (1) Interface description (reserved word is entity) (2) One or more architectural bodies (reserved word is architecture) Basic Features of VHDL D Q D FF R CLK Designed digital device entity D_FF defining D FF interface (ports) architecture of D_FF specifying the behavior of the entity VHDL representation

15. Ivan Dugic idugic@verat.net 15/29 Entity  The entity part provides system’s interface specification as seen from the outside and is generally comprised of: (1) Parameters (such as bus width or max clock frequency) (2) Connections (system input and output ports) entity DesignEntityName is -- parameters … -- connections port (ports); end entity DesignEntityName; Basic Features of VHDL

16. Ivan Dugic idugic@verat.net 16/29 Architectural bodies  Architectural bodies are specifying the behavior of the entity architecture ArchitectureName of DesignEntityName is -- signal declarations begin -- concurrent statements end architecture ArchitectureName;  There are two types of architectural bodies: algorithmic, structural  Algorithmic - at the beginning of the design process, designers usually would like to check the accuracy of the algorithm without specifying the detailed implementation  Structural - the logic design stage, detailed implementation, entity as a set of interrelated components Basic Features of VHDL

17. Ivan Dugic idugic@verat.net 17/29 Processes  Process is another major modeling element in VHDL: ProcessLabel: ProcessName (sensitivity_list_of_signals) is begin -- sequential statements; end process;  Processes are used inside architectural bodies, specifying entity behavioral in algorithmic way  Whenever a signal in sensitivity list changes, the process is activated  Process execution is similar to program execution, barring one important difference: a process generally repeats indefinitely Basic Features of VHDL

18. Ivan Dugic idugic@verat.net 18/29 Sequential and parallel processing  The statements within process are performed sequentially  The statements within architectural body are performed concurrent  Sequential and concurrent combination is called VHDL duality and it presents powerful mechanism for descriptionof complex systems Basic Features of VHDL

19. Ivan Dugic idugic@verat.net 19/29 Variables and signals  VHDL variable concept in many ways correspondents to a variable inherited from traditional sequential programming  Signals are the basic vehicle for information transmission in electronic systems  Signals model real devices’ wires and buses  Variable assignment is different from signal assignment  Main difference between variables and signals is that signal changes are visible only after process termination Basic Features of VHDL

20. Ivan Dugic idugic@verat.net 20/29 Design Process Highlights

21. Ivan Dugic idugic@verat.net 21/29 MAC (Multiply Accumulator) unit  Incoming part is based on MAC unit design and synthesis as part of Computer VLSI Systems, subject lectured by Dr. Veljko Milutinovic  Basic specification elements of MAC unit: (1) purpose – hardware support for numerous succeeding multiplication (2) Wishbone compatible (3) structural elements: FIFO, sequential multiplier, accumulator  MAC units are used as special CPU resource for digital signal processing Design Process Highlights

22. Ivan Dugic idugic@verat.net 22/29 MAC (Multiply Accumulator) unit  MAC unit conceptual scheme: Design Process Highlights FIFOSequential MultiplierAccumulator Wishbone Interface data flow control data flow MAC unit

23. Ivan Dugic idugic@verat.net 23/29 MAC (Multiply Accumulator) unit  MAC unit detailed scheme – synthesis outcome: Design Process Highlights

24. Ivan Dugic idugic@verat.net 24/29 MAC: Lessons Learned  Testing is extremely important aspect of device design  In the component design process it is essential to test all structure components of top-level entity separately, and after that top-level entity itself  While projecting MAC unit so called Regression Testing is used  Regression Testing includes testing both structural and behavioral architecture of every entity simultaneously Design Process Highlights

25. Ivan Dugic idugic@verat.net 25/29 MAC: Lessons Learned  An example of regressive testing: entity TestBench is end entity TestBench; architecture Regression of TestBench is -- signal declaration begin BehModel: entity myModel (beh) port map (…); StructModel:entity myModel (struct) port map (…); stimulus: process is begin -- stimulation end process stimulus; Design Process Highlights

26. Ivan Dugic idugic@verat.net 26/29 MAC: Lessons Learned verify: process (…) is begin assert behOutSignal_i= structOutSignal_i and behOutSignal_j = structOutSignal_j report “Implementation Error!” severity error; end process verify; end architecture Regression; Design Process Highlights

27. Ivan Dugic idugic@verat.net 27/29 MAC: Lessons Learned  Special problem in hardware component design: accommodation of VHDL source code with tool for synthesis  It is possible that VHDL code can be compiled regularly but synthesis tool registers errors  The solution of the problem: VHDL coding concerning synthesis tool requirements  It is necessary that VHDL code describes designed device as close as possible to the particular hardware elements which synthesis tool recognizes and synthesizes easily Design Process Highlights

28. Ivan Dugic idugic@verat.net 28/29 References  James R. Armstrong, F. Gail Gray, Structured Logic Design with VHDL  Peter J. Ashenden, The Designer’s Guide to VHDL  Milutinovic Veljko, Surviving the Design of a 200 MHz RISC Microprocessor: Lessons Learned

29. Ivan Dugic idugic@verat.net 29/29 Authors  Ivan Dugic, idugic@verat.netidugic@verat.net  Dr. Veljko Milutinovic, vm@galeb.etf.bg.ac.yuvm@galeb.etf.bg.ac.yu