This chapter defines reengineering as the process of rebuilding legacy software products. The rebuilt software products often have increased functionality, better performance, greater reliability, and are easier to maintain than their predecessors. Business process reengineering (BPR) defines business goals, evaluates existing business processes, and creates revised business processes that better meet current goals. Software reengineering involves inventory analysis, document restructuring, reverse engineering, program and data restructuring, and forward engineering. Many reengineering work products are the same as those generated for any software engineering process (analysis models, design models, test procedures). The final product for any reengineering process is a reengineered business process and/or the reengineered software to support it. The same SQA practices are applied to software reengineering as they would to any other software development process. Testing is used to uncover errors in content, functionality, and interoperability.
Business Process Reengineering Principles
Organize around outcomes, not tasks.
Have those people who use the output of a process, perform the process.
Incorporate information processing work into the real work that produces the raw information.
Treat geographically dispersed resources as though they were centralized.
Link parallel activities instead of integrating their results.
Put the decision point where the work is performed and build control into the process.
Capture the data once, at its source.
Business Process Reengineering Model
Business definition - business goals are identified in the context of four key drivers (cost reduction, time reduction, quality improvement, empowerment)
Process identification - processes critical to achieving business goals are identified and prioritized
Process evaluation - existing processes are analyzed and measured, costs and time consumed by processes are noted, quality/performance problems are isolated
Process specification and design - use-cases are prepared for each process to be redesigned, these use-case scenarios deliver some outcome to a customer, new tasks are designed for each process
Prototyping - used to test processes before integrating them into the business
Refinement and instantiation - based on feedback from the prototype, business processes are refined and then instantiated within a business system
Software Maintenance
Corrective maintenance (fixing errors)
Adaptive maintenance (accommodating changes in the environment or user needs)
Perfective maintenance (reengineering the application to improve performance or make the software product easier to maintain)
Preventative maintenance (modifying software to avoid anticipated future problems)
Software Reengineering Process Model
Inventory analysis - sorting active software applications by business criticality, longevity, current maintainability, and other local criteria helps to identify reengineering candidates
Document restructuring - need to decide to live with weak documentation, update poor documents if they are used, or fully rewrite the documentation for critical systems focusing on the "essential minimum"
Reverse engineering - process of design recovery - analyzing a program in an effort to create a representation of the program at some abstraction level higher than source code
Code restructuring - source code is analyzed and violations of structured programming practices are noted and repaired, the revised code also needs to be reviewed and tested
Data restructuring - usually requires full reverse engineering, current data architecture is dissected and data models are defined, existing data structures are reviewed for quality
Forward engineering - also called reclamation or renovation, recovers design information from existing source code and uses this information to reconstitute the existing system to improve its overall quality and/or performance
Reverse Engineering Concepts
Abstraction level - ideally want to be able to derive design information at the highest level possible
Completeness - level of detail provided at a given abstraction level
Interactivity - degree to which humans are integrated with automated reverse engineering tools
Directionality - one-way means the software engineer doing the maintenance activity is given all information extracted from source code, two-way means the information is fed to a reengineering tool that attempts to regenerate the old program
Extract abstractions - meaningful specification of processing performed is derived from old source code
Reverse Engineering Activities
Understanding processing - source code is analyzed at varying levels of detail (system, program, component, pattern, statement) to understand procedural abstractions and overall functionality
Understanding data
internal data structures - program code is examined with the intention of grouping related program variables
database structure - often done prior to moving from one database paradigm to another (e.g., flat file to relational)
Reverse Engineering User interfaces
What are the basic actions (e.g., key strokes or mouse operations) processed by the interface?
What is a compact description of the system's behavioral response to these actions?
What concept of equivalence of interfaces is relevant here?
Restructuring Benefits
Improved program and documentation quality
Makes programs easier to learn, improves productivity, reduces developer frustration
Reduces effort required to maintain software
Software is easier to test and debug
Types of Restructuring
Code restructuring
program logic modeled using Boolean algebra and series of transformation rules are applied to yield restructured logic
create resource exchange diagram showing data types, procedure and variables shared between modules, restructure program architecture to minimize module coupling
Data restructuring
analysis of source code
data redesign
data record standardization
data name rationalization
file or database translation
Identifying Forward Engineering Candidates
Program will continue to be used for several more years
Program is currently being used successfully
Program is likely to undergo major modification or enhancement in the future
Forward Engineering Client/Server Architectures
application functionality migrates to each client computer
new GUI interfaces implemented at client sites
database functions allocated to servers
specialized functionality may remain at server site
new communications, security, archiving, and control requirements must be established at both client and server sites
Forward Engineering Object-oriented Architectures
existing software is reverse engineered so that appropriate data, functional, and behavioral models can be created
use-cases are created if reengineered system extends functionality of application
data models created during reverse engineering are used with CRC modeling as a basis to define classes
create class hierarchies, object-relationship models, object-behavior models and begin object-oriented design
a component-based process model may be used if a robust component library already exists
where components must be built from scratch, it may be possible to reuse algorithms and data structures from the original application
Forward Engineering User interfaces
understand the original user interface and how the data moves between the user interface and the remainder of the application
remodel the behavior implied by the existing user interface into a series of abstractions that have meaning in the context of a GUI
introduce improvements that make the mode of interaction more efficient
build and integrate the new GUI
Economics of Reengineering
Cost of maintenance = cost annual of operation and maintenance over application lifetime
Cost of reengineering = predicted return on investment reduced by cost of implementing changes and engineering risk factors
Cost benefit = Cost of reengineering - Cost of maintenance
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