Although the appearance of VHDL cod

Although the appearance of VHDL code is very different from a schematic diagram,VHDL
code is just another way to describe a circuit. Synthesis software carries out a series of
refinements and transforms a textual VHDL description to a cell-level netlist. Although
software can perform simplification and local optimization,it does not know the meaning
or intention of the code and cannot exploit alternative designs or change the architectural
of the circuit.
The quality of a design and its description are two independent factors. We can express
the initial design by a schematic diagram or by a textual VHDL program. Similarly,we
can realize and synthesize the design either manually by paper and pencil or automatically
by synthesis software. Using VHDL and synthesis software does not lead automatically
to either a good or a bad design. VHDL description and synthesis software,however, can
shield tedious implementation details and greatly simplify the realization process. They
allow us to have more time to explore and investigate alternative design ideas.
Derivation of an efficient, synthesizable VHDL description requires two major tasks:
0 Research to find an efficient design.
0 Develop VHDL code that accurately describes the design.
For a problem in digital system development, there is seldom a single unique solution.
A large number of possible designs exist. The resulting implementations differ in size and
performance and their quality may vary significantly. There is no simple, mechanical way
to derive an efficient design. It frequently relies on a designer’s experience, insight and
understanding of the problem.
After we find a design, the next step is to derive VHDL code that describes the design
accurately. Although the VHDL textual code cannot precisely specify the final structural
implementation, it describes the “big picture” that establishes the basic skeleton of the
circuit. For a complex design, it is useful to draw a rough schematic sketch to help in
locating the key components and identifying the critical path.
In addition to faithfully describing the intended design, good VHDL code should be
clear and compact, and can be easily “scaled.” Scalability concerns the amount of code
modification needed when the signal width of a circuit changes. For example, after we
develop a VHDL code for an 8-bit barrel shifter,how much modification is required if the
input is increased to 16 bits, 32 bits or even 64 bits? The development of scalable and
parameterized VHDL code is discussed in detail in Chapters 14 and 15. In this chapter, we
need only be aware of this aspect of VHDL code, and discuss it when appropriate.