Warnier/Orr diagram

Last updated August 10, 2023

A Warnier/Orr diagram (also known as a logical construction of a program/system) is a kind of hierarchical flowchart that allows the description of the organization of data and procedures. They were initially developed 1976,^[1] in France by Jean-Dominique Warnier ^[2] and in the United States by Kenneth Orr ^[3] on the foundation of Boolean algebra.^[4] This method aids the design of program structures by identifying the output and processing results and then working backwards to determine the steps and combinations of input needed to produce them.^[5] The simple graphic method used in Warnier/Orr diagrams makes the levels in the system evident and the movement of the data between them vivid.

Basic elements

{\text{Wikipedia page}}{\begin{cases}{\text{Top Section}}&{\begin{cases}{\text{Introduction}}\\{\text{Table of Contents}}\end{cases}}\\{\text{Body}}&{\begin{cases}{\underset {(1,n)}{\text{Body Section}}}&{\begin{cases}{\text{Heading}}\\{\text{Text}}\end{cases}}\end{cases}}\\{\text{End Section}}&{\begin{cases}{\text{See Also}}\\{\text{References}}\\{\text{External Links}}\end{cases}}\end{cases}}

Sample Warnier Orr Data diagram illustrating structure of a Wikipedia page.

Warnier/Orr diagrams show the processes and sequences in which they are performed. Each process is defined in a hierarchical manner i.e. it consists of sets of subprocesses, that define it. At each level, the process is shown in bracket that groups its components.

Since a process can have many different subprocesses, Warnier/Orr diagram uses a set of brackets to show each level of the system. Critical factors in software definition and development are iteration or repetition and alternation. Warnier/Orr diagrams show this very well.^{[ citation needed ]}

Using Warnier/Orr diagrams

To develop a Warnier/Orr diagram, the analyst works backwards, starting with systems output and using output oriented analysis. On paper, the development moves from the set to the element (from left to right) . First, the intended output or results of the processing are defined. At the next level, shown by inclusion with a bracket, the steps needed to produce the output are defined. Each step in turn is further defined. Additional brackets group the processes required to produce the result on the next level.

Warnier/Orr diagrams offer some distinct advantages to systems experts. They are simple in appearance and easy to understand. Yet they are powerful design tools. They have advantage of showing groupings of processes and the data that must be passed from level to level. In addition, the sequence of working backwards ensures that the system will be result oriented. This method is useful for both data and process definition. It can be used for each independently, or both can be combined on the same diagram.

Constructs in Warnier/Orr diagrams

There are four basic constructs used on Warnier/Orr diagrams: hierarchy, sequence, repetition, and alternation. There are also two slightly more advanced concepts that are occasionally needed: concurrency and recursion.

Hierarchy

Hierarchy is the most fundamental of all of the Warnier/Orr constructs. It is simply a nested group of sets and subsets shown as a set of nested brackets. Each bracket on the diagram (depending on how you represent it, the character is usually more like a brace "{" than a bracket "[", but we call them "brackets") represents one level of hierarchy. The hierarchy or structure that is represented on the diagram can show the organization of data or processing. However, both data and processing are never shown on the same diagram.

Sequence

Sequence is the simplest structure to show on a Warnier/Orr diagram. Within one level of hierarchy, the features listed are shown in the order in which they occur. In other words, the step listed first is the first that will be executed (if the diagram reflects a process), while the step listed last is the last that will be executed. Similarly with data, the data field listed first is the first that is encountered when looking at the data, the data field listed last is the final one encountered.

Repetition

Repetition is the representation of a classic "loop" in programming terms. It occurs whenever the same set of data occurs over and over again (for a data structure) or whenever the same group of actions is to occur over and over again (for a processing structure). Repetition is indicated by placing a set of numbers inside parentheses beneath the repeating set.

Typically there are two numbers listed in the parentheses, representing the fewest and the most number of times the set will repeat. By convention the first letter of the repeating set is the letter chosen to represent the maximum.

While the minimum bound and maximum bound can technically be anything, they are most often either "(1,n)" as in the example, or "(0,n)." When used to depict processing, the "(1,n)" repetition is classically known as a "DoUntil" loop, while the "(0,n)" repetition is called a "DoWhile" loop. On the Warnier/Orr diagram, however, there is no distinction between the two different types of repetition, other than the minimum bound value.

On occasion, the minimum and maximum bound are predefined and not likely to change: for instance the set "Day" occurs within the set "Month" from 28 to 31 times (since the smallest month has 28 days, the largest months, 31). This is not likely to change. And on occasion, the minimum and maximum are fixed at the same number.

In general, though, it is a bad idea to "hard code" a constant other than "0" or "1" in a number of times clause—the design should be flexible enough to allow for changes in the number of times without changes to the design. For instance, if a company has 38 employees at the time a design is done, hard coding a "38" as the "number of employees" within company would certainly not be as flexible as designing "(1,n)".

The number of times clause is always an operator attached to some set (i.e., the name of some bracket), and is never attached to an element (a diagram feature which does not decompose into smaller features). The reason for this will become more apparent as we continue to work with the diagrams. For now, you will have to accept this as a formation rule for a correct diagram.

Alternation

Alternation, or selection, is the traditional "decision" process whereby a determination is made to execute one process or another. The Exclusive OR symbol (the plus sign inside the circle) indicates that the sets immediately above and below it are mutually exclusive (if one is present the other is not). This diagram indicates that an Employee is either Management or Non-Management, one Employee cannot be both. It is also permissible to use a "negation bar" above an alternative in a manner similar to engineering notation. The bar is read by simply using the word "not".

Alternatives do not have to be binary as in the previous examples, but may be many-way alternatives.

Concurrency

Concurrency is one of the two advanced constructs used in the methodology. It is used whenever sequence is unimportant. For instance, years and weeks operate concurrently (or at the same time) within our calendar. The concurrency operator is rarely used in program design (since most languages do not support true concurrent processing anyway), but does come into play when resolving logical and physical data structure clashes.

Recursion

Recursion is the least used of the constructs. It is used to indicate that a set contains an earlier or a less ordered version of itself. In the classic "bill of materials" problem components contain parts and other sub-components. Sub-components also contain sub-sub-components, and so on. The doubled bracket indicates that the set is recursive. Data structures that are truly recursive are rather rare.

Applications

One source mentioned Warnier-Orr diagrams (along with Booch diagram s, object diagram s) as an inferior method for model-driven software architecture design.^[6]

Related Research Articles

In computer programming, a macro is a rule or pattern that specifies how a certain input should be mapped to a replacement output. Applying a macro to an input is known as macro expansion. The input and output may be a sequence of lexical tokens or characters, or a syntax tree. Character macros are supported in software applications to make it easy to invoke common command sequences. Token and tree macros are supported in some programming languages to enable code reuse or to extend the language, sometimes for domain-specific languages.

In computer science, Backus–Naur form or Backus normal form (BNF) is a metasyntax notation for context-free grammars, often used to describe the syntax of languages used in computing, such as computer programming languages, document formats, instruction sets and communication protocols. It is applied wherever exact descriptions of languages are needed: for instance, in official language specifications, in manuals, and in textbooks on programming language theory.

<span class="mw-page-title-main">Jackson structured programming</span>

Jackson structured programming (JSP) is a method for structured programming developed by British software consultant Michael A. Jackson and described in his 1975 book Principles of Program Design. The technique of JSP is to analyze the data structures of the files that a program must read as input and produce as output, and then produce a program design based on those data structures, so that the program control structure handles those data structures in a natural and intuitive way.

In computer engineering, a hardware description language (HDL) is a specialized computer language used to describe the structure and behavior of electronic circuits, and most commonly, digital logic circuits.

Software design is the process by which an agent creates a specification of a software artifact intended to accomplish goals, using a set of primitive components and subject to constraints. The term is sometimes used broadly to refer to "all the activity involved in conceptualizing, framing, implementing, commissioning, and ultimately modifying" the software, or more specifically "the activity following requirements specification and before programming, as ... [in] a stylized software engineering process."

<span class="mw-page-title-main">Systems development life cycle</span> Systems engineering terms

In systems engineering, information systems and software engineering, the systems development life cycle (SDLC), also referred to as the application development life cycle, is a process for planning, creating, testing, and deploying an information system. The SDLC concept applies to a range of hardware and software configurations, as a system can be composed of hardware only, software only, or a combination of both. There are usually six stages in this cycle: requirement analysis, design, development and testing, implementation, documentation, and evaluation.

A data-flow diagram is a way of representing a flow of data through a process or a system. The DFD also provides information about the outputs and inputs of each entity and the process itself. A data-flow diagram has no control flow — there are no decision rules and no loops. Specific operations based on the data can be represented by a flowchart.

Decomposition in computer science, also known as factoring, is breaking a complex problem or system into parts that are easier to conceive, understand, program, and maintain.

IDEF0, a compound acronym, is a function modeling methodology for describing manufacturing functions, which offers a functional modeling language for the analysis, development, reengineering and integration of information systems, business processes or software engineering analysis.

Glossary of Unified Modeling Language (UML) terms provides a compilation of terminology used in all versions of UML, along with their definitions. Any notable distinctions that may exist between versions are noted with the individual entry it applies to.

In computer programming, flow-based programming (FBP) is a programming paradigm that defines applications as networks of black box processes, which exchange data across predefined connections by message passing, where the connections are specified externally to the processes. These black box processes can be reconnected endlessly to form different applications without having to be changed internally. FBP is thus naturally component-oriented.

Object-oriented design (OOD) is the process of planning a system of interacting objects for the purpose of solving a software problem. It is one approach to software design.

In software engineering, structured analysis (SA) and structured design (SD) are methods for analyzing business requirements and developing specifications for converting practices into computer programs, hardware configurations, and related manual procedures.

In systems engineering, software engineering, and computer science, a function model or functional model is a structured representation of the functions within the modeled system or subject area.

A functional flow block diagram (FFBD) is a multi-tier, time-sequenced, step-by-step flow diagram of a system's functional flow. The term "functional" in this context is different from its use in functional programming or in mathematics, where pairing "functional" with "flow" would be ambiguous. Here, "functional flow" pertains to the sequencing of operations, with "flow" arrows expressing dependence on the success of prior operations. FFBDs may also express input and output data dependencies between functional blocks, as shown in figures below, but FFBDs primarily focus on sequencing.

A structure chart (SC) in software engineering and organizational theory is a chart which shows the breakdown of a system to its lowest manageable levels. They are used in structured programming to arrange program modules into a tree. Each module is represented by a box, which contains the module's name. The tree structure visualizes the relationships between modules.

UML state machine, also known as UML statechart, is an extension of the mathematical concept of a finite automaton in computer science applications as expressed in the Unified Modeling Language (UML) notation.

A communication protocol is a system of rules that allows two or more entities of a communications system to transmit information via any variation of a physical quantity. The protocol defines the rules, syntax, semantics, and synchronization of communication and possible error recovery methods. Protocols may be implemented by hardware, software, or a combination.

Input/output automata provide a formal model, applicable in describing most types of an asynchronous concurrent system. On its own, the I/O automaton model contains a very basic structure that enables it to model various types of distributed systems. To describe specific types of asynchronous systems, additional structure must be added to this basic model. The model presents an explicit method for describing and reasoning about system components such as processes and message channels that interact with one another, operating at arbitrary relative speeds. The I/O automata were first introduced by Nancy A. Lynch and Mark R. Tuttle in "Hierarchical correctness proofs for distributed algorithms", 1987.

Jean-Dominique Warnier (1920–1990) was an engineer in the Bull IT group, he developed and disseminated an innovative approach to the study of information systems during the 1970s. His work aims to express the fundamental laws of the rational processing of data in the service of human activities.

References

↑ Waddel, K. C.; Cross, J. H. (1988). "Survey of empirical studies of graphical representations for algorithms". Proceedings of the 1988 ACM sixteenth annual conference on Computer science - CSC '88. Atlanta, Georgia, United States: ACM Press. p. 696. doi:10.1145/322609.323161. ISBN 9780897912600. S2CID 18590219.
↑ Warnier, Jean Dominique. (1976). Logical construction of programs. New York: Van Nostrand Reinhold Co. ISBN 0442291930. OCLC 2792121.
↑ Orr, Ken. (1977). Structured systems development . New York: Yourdon Press. ISBN 0917072065. OCLC 3615720.
↑ Higgins, David, A. (October 1977). "Structured Program Design". Byte Magazine . 02 (10): 146–155.
↑ Higgins, David, A. (December 1977). "Structured Programming With Warnier-Orr Diagrams - Part 1: Design Methodology". Byte Magazine . 2 (12): 104–111.
↑ Reeves, Jack W. (1992). "What is software engineering". www.bleading-edge.com. C++ Journal. Retrieved 2023-07-25.

External links

Warnier
Dave Higgins Consulting website and original source for Wikipedia entry.
James A. Senn, Analysis & Design of Information Systems, 2nd ed., McGraw-Hill Publishing Company
Ken Orr Institute
Here is the website concerning all the works of JD WARNIER (French / English)

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Waddel, K. C.; Cross, J. H. (1988). "Survey of empirical studies of graphical representations for algorithms". Proceedings of the 1988 ACM sixteenth annual conference on Computer science - CSC '88. Atlanta, Georgia, United States: ACM Press. p. 696. doi:10.1145/322609.323161. ISBN 9780897912600. S2CID 18590219.

[2] Warnier, Jean Dominique. (1976). Logical construction of programs. New York: Van Nostrand Reinhold Co. ISBN 0442291930. OCLC 2792121.

[3] Orr, Ken. (1977). Structured systems development . New York: Yourdon Press. ISBN 0917072065. OCLC 3615720.

[4] Higgins, David, A. (October 1977). "Structured Program Design". Byte Magazine . 02 (10): 146–155.

[5] Higgins, David, A. (December 1977). "Structured Programming With Warnier-Orr Diagrams - Part 1: Design Methodology". Byte Magazine . 2 (12): 104–111.

[6] Reeves, Jack W. (1992). "What is software engineering". www.bleading-edge.com. C++ Journal. Retrieved 2023-07-25.

[1]

[2]

[3]

[4]

[5]

[6]