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Wikipedia

Software architecture

January 01, 1970

Software architecture is the set of structures needed to reason about a software system and the discipline of creating such structures and systems. Each structure comprises software elements, relations among them, and properties of both elements and relations.[1][2]

The architecture of a software system is a metaphor, analogous to the architecture of a building.[3] It functions as the blueprints for the system and the development project, which project management can later use to extrapolate the tasks necessary to be executed by the teams and people involved.

Software architecture design is commonly juxtaposed with software application design. Whilst application design focuses on the design of the processes and data supporting the required functionality (the services offered by the system), software architecture design focuses on designing the infrastructure within which application functionality can be realized and executed such that the functionality is provided in a way which meets the system's non-functional requirements.

Software architecture is about making fundamental structural choices that are costly to change once implemented. Software architecture choices include specific structural options from possibilities in the design of the software.

For example, the systems that controlled the Space Shuttle launch vehicle had the requirement of being very fast and very reliable. Therefore, an appropriate real-time computing language would need to be chosen. Additionally, to satisfy the need for reliability the choice could be made to have multiple redundant and independently produced copies of the program, and to run these copies on independent hardware while cross-checking results.

Documenting software architecture facilitates communication between stakeholders, captures early decisions about the high-level design, and allows the reuse of design components between projects.[4]: 29–35 

Software architecture activities

Scope edit

Opinions vary as to the scope of software architectures:[5]

  • Macroscopic system structure: this refers to architecture as a higher-level abstraction of a software system that consists of a collection of computational components together with connectors that describe the interaction between these components.[6]
  • The important stuff—whatever that is: this refers to the fact that software architects should concern themselves with those decisions that have high impact on the system and its stakeholders.[7]
  • That which is fundamental to understanding a system in its environment[8]
  • Things that people perceive as hard to change: since designing the architecture takes place at the beginning of a software system's lifecycle, the architect should focus on decisions that "have to" be right the first time. Following this line of thought, architectural design issues may become non-architectural once their irreversibility can be overcome.[7]
  • A set of architectural design decisions: software architecture should not be considered merely a set of models or structures, but should include the decisions that lead to these particular structures, and the rationale behind them.[9] This insight has led to substantial research into software architecture knowledge management.[10]

There is no sharp distinction between software architecture versus design and requirements engineering (see Related fields below). They are all part of a "chain of intentionality" from high-level intentions to low-level details.[11]: 18 

Characteristics edit

Software architecture exhibits the following:

Multitude of stakeholders: software systems have to cater to a variety of stakeholders such as business managers, owners, users, and operators. These stakeholders all have their own concerns with respect to the system. Balancing these concerns and demonstrating that they are addressed is part of designing the system.[4]: 29–31  This implies that architecture involves dealing with a broad variety of concerns and stakeholders, and has a multidisciplinary nature.

Separation of concerns: the established way for architects to reduce complexity is to separate the concerns that drive the design. Architecture documentation shows that all stakeholder concerns are addressed by modeling and describing the architecture from separate points of view associated with the various stakeholder concerns.[12] These separate descriptions are called architectural views (see for example the 4+1 architectural view model).

Quality-driven: classic software design approaches (e.g. Jackson Structured Programming) were driven by required functionality and the flow of data through the system, but the current insight[4]: 26–28  is that the architecture of a software system is more closely related to its quality attributes such as fault-tolerance, backward compatibility, extensibility, reliability, maintainability, availability, security, usability, and other such –ilities. Stakeholder concerns often translate into requirements on these quality attributes, which are variously called non-functional requirements, extra-functional requirements, behavioral requirements, or quality attribute requirements.

Recurring styles: like building architecture, the software architecture discipline has developed standard ways to address recurring concerns. These "standard ways" are called by various names at various levels of abstraction. Common terms for recurring solutions are architectural style,[11]: 273–277  tactic,[4]: 70–72  reference architecture and architectural pattern.[13][14][4]: 203–205 

Conceptual integrity: a term introduced by Fred Brooks in his 1975 book The Mythical Man-Month to denote the idea that the architecture of a software system represents an overall vision of what it should do and how it should do it. This vision should be separated from its implementation. The architect assumes the role of "keeper of the vision", making sure that additions to the system are in line with the architecture, hence preserving conceptual integrity.[15]: 41–50 

Cognitive constraints: An observation first made in a 1967 paper by computer programmer Melvin Conway that organizations which design systems are constrained to produce designs which are copies of the communication structures of these organizations.[16] Fred Brooks introduced it to a wider audience when he cited the paper and the idea in The Mythical Man-Month, calling it Conway's Law.

Motivation edit

Software architecture is an "intellectually graspable" abstraction of a complex system.[4]: 5–6  This abstraction provides a number of benefits:

  • It gives a basis for analysis of software systems' behavior before the system has been built.[3] The ability to verify that a future software system fulfills its stakeholders' needs without actually having to build it represents substantial cost-saving and risk-mitigation.[17] A number of techniques have been developed to perform such analyses, such as ATAM or by creating a visual representation of the software system.
  • It provides a basis for re-use of elements and decisions.[3][4]: 35  A complete software architecture or parts of it, like individual architectural strategies and decisions, can be re-used across multiple systems whose stakeholders require similar quality attributes or functionality, saving design costs and mitigating the risk of design mistakes.
  • It supports early design decisions that impact a system's development, deployment, and maintenance life.[4]: 31  Getting the early, high-impact decisions right is important to prevent schedule and budget overruns.
  • It facilitates communication with stakeholders, contributing to a system that better fulfills their needs.[4]: 29–31  Communicating about complex systems from the point of view of stakeholders helps them understand the consequences of their stated requirements and the design decisions based on them. Architecture gives the ability to communicate about design decisions before the system is implemented, when they are still relatively easy to adapt.
  • It helps in risk management. Software architecture helps to reduce risks and chance of failure.[11]: 18 
  • It enables cost reduction. Software architecture is a means to manage risk and costs in complex IT projects.[18]

History edit

The comparison between software design and (civil) architecture was first drawn in the late 1960s,[19] but the term "software architecture" did not see widespread usage until the 1990s.[20] The field of computer science had encountered problems associated with complexity since its formation.[21] Earlier problems of complexity were solved by developers by choosing the right data structures, developing algorithms, and by applying the concept of separation of concerns. Although the term "software architecture" is relatively new to the industry, the fundamental principles of the field have been applied sporadically by software engineering pioneers since the mid-1980s. Early attempts to capture and explain software architecture of a system were imprecise and disorganized, often characterized by a set of box-and-line diagrams.[22]

Software architecture as a concept has its origins in the research of Edsger Dijkstra in 1968 and David Parnas in the early 1970s. These scientists emphasized that the structure of a software system matters and getting the structure right is critical. During the 1990s there was a concerted effort to define and codify fundamental aspects of the discipline, with research work concentrating on architectural styles (patterns), architecture description languages, architecture documentation, and formal methods.[23]

Research institutions have played a prominent role in furthering software architecture as a discipline. Mary Shaw and David Garlan of Carnegie Mellon wrote a book titled Software Architecture: Perspectives on an Emerging Discipline in 1996, which promoted software architecture concepts such as components, connectors, and styles. The University of California, Irvine's Institute for Software Research's efforts in software architecture research is directed primarily in architectural styles, architecture description languages, and dynamic architectures.

IEEE 1471-2000, "Recommended Practice for Architecture Description of Software-Intensive Systems", was the first formal standard in the area of software architecture. It was adopted in 2007 by ISO as ISO/IEC 42010:2007. In November 2011, IEEE 1471–2000 was superseded by ISO/IEC/IEEE 42010:2011, "Systems and software engineering – Architecture description" (jointly published by IEEE and ISO).[12]

While in IEEE 1471, software architecture was about the architecture of "software-intensive systems", defined as "any system where software contributes essential influences to the design, construction, deployment, and evolution of the system as a whole", the 2011 edition goes a step further by including the ISO/IEC 15288 and ISO/IEC 12207 definitions of a system, which embrace not only hardware and software, but also "humans, processes, procedures, facilities, materials and naturally occurring entities". This reflects the relationship between software architecture, enterprise architecture and solution architecture.

Architecture activities edit

There are many activities that a software architect performs. A software architect typically works with project managers, discusses architecturally significant requirements with stakeholders, designs a software architecture, evaluates a design, communicates with designers and stakeholders, documents the architectural design and more.[24] There are four core activities in software architecture design.[25] These core architecture activities are performed iteratively and at different stages of the initial software development life-cycle, as well as over the evolution of a system.

Architectural analysis is the process of understanding the environment in which a proposed system will operate and determining the requirements for the system. The input or requirements to the analysis activity can come from any number of stakeholders and include items such as:

  • what the system will do when operational (the functional requirements)
  • how well the system will perform runtime non-functional requirements such as reliability, operability, performance efficiency, security, compatibility defined in ISO/IEC 25010:2011 standard[26]
  • development-time of non-functional requirements such as maintainability and transferability defined in ISO 25010:2011 standard[26]
  • business requirements and environmental contexts of a system that may change over time, such as legal, social, financial, competitive, and technology concerns[27]

The outputs of the analysis activity are those requirements that have a measurable impact on a software system's architecture, called architecturally significant requirements.[28]

Architectural synthesis or design is the process of creating an architecture. Given the architecturally significant requirements determined by the analysis, the current state of the design and the results of any evaluation activities, the design is created and improved.[25][4]: 311–326 

Architecture evaluation is the process of determining how well the current design or a portion of it satisfies the requirements derived during analysis. An evaluation can occur whenever an architect is considering a design decision, it can occur after some portion of the design has been completed, it can occur after the final design has been completed or it can occur after the system has been constructed. Some of the available software architecture evaluation techniques include Architecture Tradeoff Analysis Method (ATAM) and TARA.[29] Frameworks for comparing the techniques are discussed in frameworks such as SARA Report[17] and Architecture Reviews: Practice and Experience.[30]

Architecture evolution is the process of maintaining and adapting an existing software architecture to meet changes in requirements and environment. As software architecture provides a fundamental structure of a software system, its evolution and maintenance would necessarily impact its fundamental structure. As such, architecture evolution is concerned with adding new functionality as well as maintaining existing functionality and system behavior.

Architecture requires critical supporting activities. These supporting activities take place throughout the core software architecture process. They include knowledge management and communication, design reasoning and decision-making, and documentation.

Architecture supporting activities edit

Software architecture supporting activities are carried out during core software architecture activities. These supporting activities assist a software architect to carry out analysis, synthesis, evaluation, and evolution. For instance, an architect has to gather knowledge, make decisions, and document during the analysis phase.

  • Knowledge management and communication is the act of exploring and managing knowledge that is essential to designing a software architecture. A software architect does not work in isolation. They get inputs, functional and non-functional requirements, and design contexts, from various stakeholders; and provide outputs to stakeholders. Software architecture knowledge is often tacit and is retained in the heads of stakeholders. Software architecture knowledge management activity is about finding, communicating, and retaining knowledge. As software architecture design issues are intricate and interdependent, a knowledge gap in design reasoning can lead to incorrect software architecture design.[24][31] Examples of knowledge management and communication activities include searching for design patterns, prototyping, asking experienced developers and architects, evaluating the designs of similar systems, sharing knowledge with other designers and stakeholders, and documenting experience on a wiki page.
  • Design reasoning and decision making is the activity of evaluating design decisions. This activity is fundamental to all three core software architecture activities.[9][32] It entails gathering and associating decision contexts, formulating design decision problems, finding solution options and evaluating tradeoffs before making decisions. This process occurs at different levels of decision granularity while evaluating significant architectural requirements and software architecture decisions, and software architecture analysis, synthesis, and evaluation. Examples of reasoning activities include understanding the impacts of a requirement or a design on quality attributes, questioning the issues that a design might cause, assessing possible solution options, and evaluating the tradeoffs between solutions.
  • Documentation is the act of recording the design generated during the software architecture process. System design is described using several views that frequently include a static view showing the code structure of the system, a dynamic view showing the actions of the system during execution, and a deployment view showing how a system is placed on hardware for execution. Kruchten's 4+1 view suggests a description of commonly used views for documenting software architecture;[33] Documenting Software Architectures: Views and Beyond has descriptions of the kinds of notations that could be used within the view description.[1] Examples of documentation activities are writing a specification, recording a system design model, documenting a design rationale, developing a viewpoint, documenting views.

Software architecture topics edit

Software architecture description edit

Main article: Software architecture description

Software architecture description involves the principles and practices of modeling and representing architectures, using mechanisms such as architecture description languages, architecture viewpoints, and architecture frameworks.

Architecture description languages edit

Main article: Architecture description language

An architecture description language (ADL) is any means of expression used to describe a software architecture (ISO/IEC/IEEE 42010). Many special-purpose ADLs have been developed since the 1990s, including AADL (SAE standard), Wright (developed by Carnegie Mellon), Acme (developed by Carnegie Mellon), xADL (developed by UCI), Darwin (developed by Imperial College London), DAOP-ADL (developed by University of Málaga), SBC-ADL (developed by National Sun Yat-Sen University), and ByADL (University of L'Aquila, Italy).

Architecture viewpoints edit

Main article: View model
 
4+1 architectural view model.

Software architecture descriptions are commonly organized into views, which are analogous to the different types of blueprints made in building architecture. Each view addresses a set of system concerns, following the conventions of its viewpoint, where a viewpoint is a specification that describes the notations, modeling, and analysis techniques to use in a view that expresses the architecture in question from the perspective of a given set of stakeholders and their concerns (ISO/IEC/IEEE 42010). The viewpoint specifies not only the concerns framed (i.e., to be addressed) but the presentation, model kinds used, conventions used and any consistency (correspondence) rules to keep a view consistent with other views.

Architecture frameworks edit

Main article: Architecture framework

An architecture framework captures the "conventions, principles and practices for the description of architectures established within a specific domain of application and/or community of stakeholders" (ISO/IEC/IEEE 42010). A framework is usually implemented in terms of one or more viewpoints or ADLs.

Architectural styles and patterns edit

An architectural pattern is a general, reusable solution to a commonly occurring problem in software architecture within a given context. Architectural patterns are often documented as software design patterns.

Following traditional building architecture, a 'software architectural style' is a specific method of construction, characterized by the features that make it notable" (architectural style).

An architectural style defines: a family of systems in terms of a pattern of structural organization; a vocabulary of components and connectors, with constraints on how they can be combined.[34]

Architectural styles are reusable 'packages' of design decisions and constraints that are applied to an architecture to induce chosen desirable qualities.[35]

There are many recognized architectural patterns and styles, among them:

Some treat architectural patterns and architectural styles as the same,[36] some treat styles as specializations of patterns. What they have in common is both patterns and styles are idioms for architects to use, they "provide a common language"[36] or "vocabulary"[34] with which to describe classes of systems.

Software architecture and agile development edit

Main article: Agile development

There are also concerns that software architecture leads to too much big design up front, especially among proponents of agile software development. A number of methods have been developed to balance the trade-offs of up-front design and agility,[37] including the agile method DSDM which mandates a "Foundations" phase during which "just enough" architectural foundations are laid. IEEE Software devoted a special issue to the interaction between agility and architecture.

Software architecture erosion edit

Software architecture erosion refers to a gradual gap between the intended and implemented architecture of a software system over time.[38] The phenomenon of software architecture erosion was initially brought to light in 1992 by Perry and Wolf alongside their definition of software architecture [3].

Software architecture erosion may occur in each stage of the software development life cycle and has varying impacts on the development speed and the cost of maintenance. Software architecture erosion occurs due to various reasons, such as architectural violations, the accumulation of technical debt, and knowledge vaporization.[39] A famous case of architecture erosion is the failure of Mozilla Web browser.[40] Mozilla is an application created by Netscape with a complex codebase that became harder to maintain due to continuous changes. Due to initial poor design and growing architecture erosion, Netscape spent two years redeveloping the Mozilla Web browser, showing how important it is to manage architecture erosion to avoid extensive repair efforts, time and cost losses.

Architecture erosion can decrease software performance, substantially increase evolutionary costs, and degrade software quality. Various approaches and tools have been proposed to detect architecture erosion. These approaches are primarily classified into four categories: consistency-based, evolution-based, and defect-based, and decision-based approach.[38] Besides, the measures used to address architecture erosion contains two main types: preventative and remedial measures.[38]

Software architecture recovery edit

Main article: Software architecture recovery

Software architecture recovery (or reconstruction, or reverse engineering) includes the methods, techniques, and processes to uncover a software system's architecture from available information, including its implementation and documentation. Architecture recovery is often necessary to make informed decisions in the face of obsolete or out-of-date documentation and architecture erosion: implementation and maintenance decisions diverging from the envisioned architecture.[41] Practices exist to recover software architecture as static program analysis. This is a part of the subjects covered by the software intelligence practice.

Related fields edit

Design edit

Main article: Software design

Architecture is design but not all design is architectural.[1] In practice, the architect is the one who draws the line between software architecture (architectural design) and detailed design (non-architectural design). There are no rules or guidelines that fit all cases, although there have been attempts to formalize the distinction. According to the Intension/Locality Hypothesis,[42] the distinction between architectural and detailed design is defined by the Locality Criterion,[42] according to which a statement about software design is non-local (architectural) if and only if a program that satisfies it can be expanded into a program that does not. For example, the client–server style is architectural (strategic) because a program that is built on this principle can be expanded into a program that is not client–server—for example, by adding peer-to-peer nodes.

Requirements engineering edit

Main article: Requirements engineering

Requirements engineering and software architecture can be seen as complementary approaches: while software architecture targets the 'solution space' or the 'how', requirements engineering addresses the 'problem space' or the 'what'.[43] Requirements engineering entails the elicitation, negotiation, specification, validation, documentation, and management of requirements. Both requirements engineering and software architecture revolve around stakeholder concerns, needs, and wishes.

There is considerable overlap between requirements engineering and software architecture, as evidenced for example by a study into five industrial software architecture methods that concludes that "the inputs (goals, constraints, etc.) are usually ill-defined, and only get discovered or better understood as the architecture starts to emerge" and that while "most architectural concerns are expressed as requirements on the system, they can also include mandated design decisions".[25] In short, required behavior impacts solution architecture, which in turn may introduce new requirements.[44] Approaches such as the Twin Peaks model[45] aim to exploit the synergistic relation between requirements and architecture.

Other types of 'architecture' edit

Main articles: Computer architecture, Systems architecture, and Enterprise architecture
Computer architecture
Computer architecture targets the internal structure of a computer system, in terms of collaborating hardware components such as the CPU – or processor – the bus and the memory.
Serverless architecture
Serverless architecture is a cloud computing paradigm that is often misunderstood as being server-free. It essentially shifts server management responsibilities from developers to cloud service providers. This allows businesses to run their backend code on cloud infrastructure, eliminating the need for physical server management. The event-driven approach of serverless architecture relies on small, task-specific functions that are executed on-demand. These functions are known as Function as a Service (FaaS), and they offer cost-efficiency through a pay-as-you-go billing model and dynamic resource scaling based on application demand.[46][better source needed]
Systems architecture
The term systems architecture has originally been applied to the architecture of systems that consist of both hardware and software. The main concern addressed by the systems architecture is then the integration of software and hardware in a complete, correctly working device. In another common – much broader – meaning, the term applies to the architecture of any complex system which may be of a technical, sociotechnical or social nature.
Enterprise architecture
The goal of enterprise architecture is to "translate business vision and strategy into effective enterprise". Enterprise architecture frameworks, such as TOGAF and the Zachman Framework, usually distinguish between different enterprise architecture layers. Although terminology differs from framework to framework, many include at least a distinction between a business layer, an application (or information) layer, and a technology layer. Enterprise architecture addresses among others the alignment between these layers, usually in a top-down approach.

See also edit

References edit

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Further reading edit

  • Richards, Mark (2020). Fundamentals of Software Architecture: An Engineering Approach. O'Reilly Media. ISBN 9781492043454.
  • Len, Bass (2012). Software Architecture in Practice (3rd ed.). Addison-Wesley Professional. ISBN 9780321815736. - This book covers the fundamental concepts of the discipline. The theme is centered on achieving quality attributes of a system.
  • Clements, Paul (2010). Documenting Software Architectures: Views and Beyond (2nd ed.). Addison-Wesley Professional. ISBN 9780321552686. - This book describes what software architecture is and shows how to document it in multiple views, using UML and other notations. It also explains how to complement the architecture views with behavior, software interface, and rationale documentation. Accompanying the book is a wiki that contains an example of software architecture documentation.
  • Bell, Michael (2008). Bell, Michael (ed.). Service-Oriented Modeling: Service Analysis, Design, and Architecture. Wiley. doi:10.1002/9781119198864. ISBN 9780470255704.
  • Shan, Tony; Hua, Winnie (October 2006). "Solution Architecting Mechanism". 2006 10th IEEE International Enterprise Distributed Object Computing Conference (EDOC'06). pp. 23–32. doi:10.1109/EDOC.2006.54. ISBN 978-0-7695-2558-7. S2CID 8361936.
  • Garzás, Javier; Piattini, Mario (2005). "An ontology for micro-architectural design knowledge". IEEE Software. 22 (2): 28–33. doi:10.1109/MS.2005.26. S2CID 17639072.
  • Fowler, Martin (September 2003). "Who Needs an Architect?" (PDF). IEEE Software. 20 (5). doi:10.1109/MS.2003.1231144. S2CID 356506.
  • Kazman, Rick (May 2003). "Architecture, Design, Implementation" (PDF). Software Engineering Institute. (PDF) from the original on 2015-09-21. - On the distinction between architectural design and detailed design.
  • Kruchten, Philippe (1995). "Architectural Blueprints – The '4+1' View Model of Software Architecture" (PDF). IEEE Software. 12 (6): 42–50. arXiv:2006.04975. doi:10.1109/52.469759. S2CID 219558624. (PDF) from the original on 2006-06-13.
  • Pautasso, Cesare (2020). Software Architecture: visual lecture notes. LeanPub. p. 689.

External links edit

 
Wikimedia Commons has media related to Software architecture.
 
Wikiquote has quotations related to Software architecture.
  • Explanation on IBM Developerworks
  • Collection of software architecture definitions at Software Engineering Institute (SEI), Carnegie Mellon University (CMU)
  • International Association of IT Architects (IASA Global), formerly known as the International Association for Software Architects (IASA)
  • SoftwareArchitecturePortal.org – website of IFIP Working Group 2.10 on Software Architecture
  • SoftwareArchitectures.com – an independent resource of information on the discipline
  • Software Architecture, chapter 1 of Roy Fielding's REST dissertation
  • When Good Architecture Goes Bad
  • The Spiral Architecture Driven Development – the SDLC based on the Spiral model aims to reduce the risks of ineffective architecture
  • Software Architecture Real Life Case Studies

January 01, 1970
software, architecture, structures, needed, reason, about, software, system, discipline, creating, such, structures, systems, each, structure, comprises, software, elements, relations, among, them, properties, both, elements, relations, architecture, software,. Software architecture is the set of structures needed to reason about a software system and the discipline of creating such structures and systems Each structure comprises software elements relations among them and properties of both elements and relations 1 2 The architecture of a software system is a metaphor analogous to the architecture of a building 3 It functions as the blueprints for the system and the development project which project management can later use to extrapolate the tasks necessary to be executed by the teams and people involved Software architecture design is commonly juxtaposed with software application design Whilst application design focuses on the design of the processes and data supporting the required functionality the services offered by the system software architecture design focuses on designing the infrastructure within which application functionality can be realized and executed such that the functionality is provided in a way which meets the system s non functional requirements Software architecture is about making fundamental structural choices that are costly to change once implemented Software architecture choices include specific structural options from possibilities in the design of the software For example the systems that controlled the Space Shuttle launch vehicle had the requirement of being very fast and very reliable Therefore an appropriate real time computing language would need to be chosen Additionally to satisfy the need for reliability the choice could be made to have multiple redundant and independently produced copies of the program and to run these copies on independent hardware while cross checking results Documenting software architecture facilitates communication between stakeholders captures early decisions about the high level design and allows the reuse of design components between projects 4 29 35 Software architecture activities Contents 1 Scope 2 Characteristics 3 Motivation 4 History 5 Architecture activities 5 1 Architecture supporting activities 6 Software architecture topics 6 1 Software architecture description 6 2 Architecture description languages 6 3 Architecture viewpoints 6 4 Architecture frameworks 6 5 Architectural styles and patterns 6 6 Software architecture and agile development 6 7 Software architecture erosion 6 8 Software architecture recovery 7 Related fields 7 1 Design 7 2 Requirements engineering 7 3 Other types of architecture 8 See also 9 References 10 Further reading 11 External linksScope editOpinions vary as to the scope of software architectures 5 Macroscopic system structure this refers to architecture as a higher level abstraction of a software system that consists of a collection of computational components together with connectors that describe the interaction between these components 6 The important stuff whatever that is this refers to the fact that software architects should concern themselves with those decisions that have high impact on the system and its stakeholders 7 That which is fundamental to understanding a system in its environment 8 Things that people perceive as hard to change since designing the architecture takes place at the beginning of a software system s lifecycle the architect should focus on decisions that have to be right the first time Following this line of thought architectural design issues may become non architectural once their irreversibility can be overcome 7 A set of architectural design decisions software architecture should not be considered merely a set of models or structures but should include the decisions that lead to these particular structures and the rationale behind them 9 This insight has led to substantial research into software architecture knowledge management 10 There is no sharp distinction between software architecture versus design and requirements engineering see Related fields below They are all part of a chain of intentionality from high level intentions to low level details 11 18 Characteristics editSoftware architecture exhibits the following Multitude of stakeholders software systems have to cater to a variety of stakeholders such as business managers owners users and operators These stakeholders all have their own concerns with respect to the system Balancing these concerns and demonstrating that they are addressed is part of designing the system 4 29 31 This implies that architecture involves dealing with a broad variety of concerns and stakeholders and has a multidisciplinary nature Separation of concerns the established way for architects to reduce complexity is to separate the concerns that drive the design Architecture documentation shows that all stakeholder concerns are addressed by modeling and describing the architecture from separate points of view associated with the various stakeholder concerns 12 These separate descriptions are called architectural views see for example the 4 1 architectural view model Quality driven classic software design approaches e g Jackson Structured Programming were driven by required functionality and the flow of data through the system but the current insight 4 26 28 is that the architecture of a software system is more closely related to its quality attributes such as fault tolerance backward compatibility extensibility reliability maintainability availability security usability and other such ilities Stakeholder concerns often translate into requirements on these quality attributes which are variously called non functional requirements extra functional requirements behavioral requirements or quality attribute requirements Recurring styles like building architecture the software architecture discipline has developed standard ways to address recurring concerns These standard ways are called by various names at various levels of abstraction Common terms for recurring solutions are architectural style 11 273 277 tactic 4 70 72 reference architecture and architectural pattern 13 14 4 203 205 Conceptual integrity a term introduced by Fred Brooks in his 1975 book The Mythical Man Month to denote the idea that the architecture of a software system represents an overall vision of what it should do and how it should do it This vision should be separated from its implementation The architect assumes the role of keeper of the vision making sure that additions to the system are in line with the architecture hence preserving conceptual integrity 15 41 50 Cognitive constraints An observation first made in a 1967 paper by computer programmer Melvin Conway that organizations which design systems are constrained to produce designs which are copies of the communication structures of these organizations 16 Fred Brooks introduced it to a wider audience when he cited the paper and the idea in The Mythical Man Month calling it Conway s Law Motivation editSoftware architecture is an intellectually graspable abstraction of a complex system 4 5 6 This abstraction provides a number of benefits It gives a basis for analysis of software systems behavior before the system has been built 3 The ability to verify that a future software system fulfills its stakeholders needs without actually having to build it represents substantial cost saving and risk mitigation 17 A number of techniques have been developed to perform such analyses such as ATAM or by creating a visual representation of the software system It provides a basis for re use of elements and decisions 3 4 35 A complete software architecture or parts of it like individual architectural strategies and decisions can be re used across multiple systems whose stakeholders require similar quality attributes or functionality saving design costs and mitigating the risk of design mistakes It supports early design decisions that impact a system s development deployment and maintenance life 4 31 Getting the early high impact decisions right is important to prevent schedule and budget overruns It facilitates communication with stakeholders contributing to a system that better fulfills their needs 4 29 31 Communicating about complex systems from the point of view of stakeholders helps them understand the consequences of their stated requirements and the design decisions based on them Architecture gives the ability to communicate about design decisions before the system is implemented when they are still relatively easy to adapt It helps in risk management Software architecture helps to reduce risks and chance of failure 11 18 It enables cost reduction Software architecture is a means to manage risk and costs in complex IT projects 18 History editThe comparison between software design and civil architecture was first drawn in the late 1960s 19 but the term software architecture did not see widespread usage until the 1990s 20 The field of computer science had encountered problems associated with complexity since its formation 21 Earlier problems of complexity were solved by developers by choosing the right data structures developing algorithms and by applying the concept of separation of concerns Although the term software architecture is relatively new to the industry the fundamental principles of the field have been applied sporadically by software engineering pioneers since the mid 1980s Early attempts to capture and explain software architecture of a system were imprecise and disorganized often characterized by a set of box and line diagrams 22 Software architecture as a concept has its origins in the research of Edsger Dijkstra in 1968 and David Parnas in the early 1970s These scientists emphasized that the structure of a software system matters and getting the structure right is critical During the 1990s there was a concerted effort to define and codify fundamental aspects of the discipline with research work concentrating on architectural styles patterns architecture description languages architecture documentation and formal methods 23 Research institutions have played a prominent role in furthering software architecture as a discipline Mary Shaw and David Garlan of Carnegie Mellon wrote a book titled Software Architecture Perspectives on an Emerging Discipline in 1996 which promoted software architecture concepts such as components connectors and styles The University of California Irvine s Institute for Software Research s efforts in software architecture research is directed primarily in architectural styles architecture description languages and dynamic architectures IEEE 1471 2000 Recommended Practice for Architecture Description of Software Intensive Systems was the first formal standard in the area of software architecture It was adopted in 2007 by ISO as ISO IEC 42010 2007 In November 2011 IEEE 1471 2000 was superseded by ISO IEC IEEE 42010 2011 Systems and software engineering Architecture description jointly published by IEEE and ISO 12 While in IEEE 1471 software architecture was about the architecture of software intensive systems defined as any system where software contributes essential influences to the design construction deployment and evolution of the system as a whole the 2011 edition goes a step further by including the ISO IEC 15288 and ISO IEC 12207 definitions of a system which embrace not only hardware and software but also humans processes procedures facilities materials and naturally occurring entities This reflects the relationship between software architecture enterprise architecture and solution architecture Architecture activities editThere are many activities that a software architect performs A software architect typically works with project managers discusses architecturally significant requirements with stakeholders designs a software architecture evaluates a design communicates with designers and stakeholders documents the architectural design and more 24 There are four core activities in software architecture design 25 These core architecture activities are performed iteratively and at different stages of the initial software development life cycle as well as over the evolution of a system Architectural analysis is the process of understanding the environment in which a proposed system will operate and determining the requirements for the system The input or requirements to the analysis activity can come from any number of stakeholders and include items such as what the system will do when operational the functional requirements how well the system will perform runtime non functional requirements such as reliability operability performance efficiency security compatibility defined in ISO IEC 25010 2011 standard 26 development time of non functional requirements such as maintainability and transferability defined in ISO 25010 2011 standard 26 business requirements and environmental contexts of a system that may change over time such as legal social financial competitive and technology concerns 27 The outputs of the analysis activity are those requirements that have a measurable impact on a software system s architecture called architecturally significant requirements 28 Architectural synthesis or design is the process of creating an architecture Given the architecturally significant requirements determined by the analysis the current state of the design and the results of any evaluation activities the design is created and improved 25 4 311 326 Architecture evaluation is the process of determining how well the current design or a portion of it satisfies the requirements derived during analysis An evaluation can occur whenever an architect is considering a design decision it can occur after some portion of the design has been completed it can occur after the final design has been completed or it can occur after the system has been constructed Some of the available software architecture evaluation techniques include Architecture Tradeoff Analysis Method ATAM and TARA 29 Frameworks for comparing the techniques are discussed in frameworks such as SARA Report 17 and Architecture Reviews Practice and Experience 30 Architecture evolution is the process of maintaining and adapting an existing software architecture to meet changes in requirements and environment As software architecture provides a fundamental structure of a software system its evolution and maintenance would necessarily impact its fundamental structure As such architecture evolution is concerned with adding new functionality as well as maintaining existing functionality and system behavior Architecture requires critical supporting activities These supporting activities take place throughout the core software architecture process They include knowledge management and communication design reasoning and decision making and documentation Architecture supporting activities edit Software architecture supporting activities are carried out during core software architecture activities These supporting activities assist a software architect to carry out analysis synthesis evaluation and evolution For instance an architect has to gather knowledge make decisions and document during the analysis phase Knowledge management and communication is the act of exploring and managing knowledge that is essential to designing a software architecture A software architect does not work in isolation They get inputs functional and non functional requirements and design contexts from various stakeholders and provide outputs to stakeholders Software architecture knowledge is often tacit and is retained in the heads of stakeholders Software architecture knowledge management activity is about finding communicating and retaining knowledge As software architecture design issues are intricate and interdependent a knowledge gap in design reasoning can lead to incorrect software architecture design 24 31 Examples of knowledge management and communication activities include searching for design patterns prototyping asking experienced developers and architects evaluating the designs of similar systems sharing knowledge with other designers and stakeholders and documenting experience on a wiki page Design reasoning and decision making is the activity of evaluating design decisions This activity is fundamental to all three core software architecture activities 9 32 It entails gathering and associating decision contexts formulating design decision problems finding solution options and evaluating tradeoffs before making decisions This process occurs at different levels of decision granularity while evaluating significant architectural requirements and software architecture decisions and software architecture analysis synthesis and evaluation Examples of reasoning activities include understanding the impacts of a requirement or a design on quality attributes questioning the issues that a design might cause assessing possible solution options and evaluating the tradeoffs between solutions Documentation is the act of recording the design generated during the software architecture process System design is described using several views that frequently include a static view showing the code structure of the system a dynamic view showing the actions of the system during execution and a deployment view showing how a system is placed on hardware for execution Kruchten s 4 1 view suggests a description of commonly used views for documenting software architecture 33 Documenting Software Architectures Views and Beyond has descriptions of the kinds of notations that could be used within the view description 1 Examples of documentation activities are writing a specification recording a system design model documenting a design rationale developing a viewpoint documenting views Software architecture topics editSoftware architecture description edit Main article Software architecture description Software architecture description involves the principles and practices of modeling and representing architectures using mechanisms such as architecture description languages architecture viewpoints and architecture frameworks Architecture description languages edit Main article Architecture description language An architecture description language ADL is any means of expression used to describe a software architecture ISO IEC IEEE 42010 Many special purpose ADLs have been developed since the 1990s including AADL SAE standard Wright developed by Carnegie Mellon Acme developed by Carnegie Mellon xADL developed by UCI Darwin developed by Imperial College London DAOP ADL developed by University of Malaga SBC ADL developed by National Sun Yat Sen University and ByADL University of L Aquila Italy Architecture viewpoints edit Main article View model nbsp 4 1 architectural view model Software architecture descriptions are commonly organized into views which are analogous to the different types of blueprints made in building architecture Each view addresses a set of system concerns following the conventions of its viewpoint where a viewpoint is a specification that describes the notations modeling and analysis techniques to use in a view that expresses the architecture in question from the perspective of a given set of stakeholders and their concerns ISO IEC IEEE 42010 The viewpoint specifies not only the concerns framed i e to be addressed but the presentation model kinds used conventions used and any consistency correspondence rules to keep a view consistent with other views Architecture frameworks edit Main article Architecture framework An architecture framework captures the conventions principles and practices for the description of architectures established within a specific domain of application and or community of stakeholders ISO IEC IEEE 42010 A framework is usually implemented in terms of one or more viewpoints or ADLs Architectural styles and patterns edit An architectural pattern is a general reusable solution to a commonly occurring problem in software architecture within a given context Architectural patterns are often documented as software design patterns Following traditional building architecture a software architectural style is a specific method of construction characterized by the features that make it notable architectural style An architectural style defines a family of systems in terms of a pattern of structural organization a vocabulary of components and connectors with constraints on how they can be combined 34 Architectural styles are reusable packages of design decisions and constraints that are applied to an architecture to induce chosen desirable qualities 35 There are many recognized architectural patterns and styles among them Blackboard Client server 2 tier 3 tier n tier cloud computing exhibit this style Component based Data centric Event driven or implicit invocation Layered or multilayered architecture Microservices architecture Monolithic application Peer to peer P2P Pipes and filters Plug ins Reactive architecture Representational state transfer REST Rule based Service oriented Shared nothing architecture Space based architecture Serverless architecture Some treat architectural patterns and architectural styles as the same 36 some treat styles as specializations of patterns What they have in common is both patterns and styles are idioms for architects to use they provide a common language 36 or vocabulary 34 with which to describe classes of systems Software architecture and agile development edit Main article Agile development There are also concerns that software architecture leads to too much big design up front especially among proponents of agile software development A number of methods have been developed to balance the trade offs of up front design and agility 37 including the agile method DSDM which mandates a Foundations phase during which just enough architectural foundations are laid IEEE Software devoted a special issue to the interaction between agility and architecture Software architecture erosion edit Software architecture erosion refers to a gradual gap between the intended and implemented architecture of a software system over time 38 The phenomenon of software architecture erosion was initially brought to light in 1992 by Perry and Wolf alongside their definition of software architecture 3 Software architecture erosion may occur in each stage of the software development life cycle and has varying impacts on the development speed and the cost of maintenance Software architecture erosion occurs due to various reasons such as architectural violations the accumulation of technical debt and knowledge vaporization 39 A famous case of architecture erosion is the failure of Mozilla Web browser 40 Mozilla is an application created by Netscape with a complex codebase that became harder to maintain due to continuous changes Due to initial poor design and growing architecture erosion Netscape spent two years redeveloping the Mozilla Web browser showing how important it is to manage architecture erosion to avoid extensive repair efforts time and cost losses Architecture erosion can decrease software performance substantially increase evolutionary costs and degrade software quality Various approaches and tools have been proposed to detect architecture erosion These approaches are primarily classified into four categories consistency based evolution based and defect based and decision based approach 38 Besides the measures used to address architecture erosion contains two main types preventative and remedial measures 38 Software architecture recovery edit Main article Software architecture recovery Software architecture recovery or reconstruction or reverse engineering includes the methods techniques and processes to uncover a software system s architecture from available information including its implementation and documentation Architecture recovery is often necessary to make informed decisions in the face of obsolete or out of date documentation and architecture erosion implementation and maintenance decisions diverging from the envisioned architecture 41 Practices exist to recover software architecture as static program analysis This is a part of the subjects covered by the software intelligence practice Related fields editDesign edit Main article Software design Architecture is design but not all design is architectural 1 In practice the architect is the one who draws the line between software architecture architectural design and detailed design non architectural design There are no rules or guidelines that fit all cases although there have been attempts to formalize the distinction According to the Intension Locality Hypothesis 42 the distinction between architectural and detailed design is defined by the Locality Criterion 42 according to which a statement about software design is non local architectural if and only if a program that satisfies it can be expanded into a program that does not For example the client server style is architectural strategic because a program that is built on this principle can be expanded into a program that is not client server for example by adding peer to peer nodes Requirements engineering edit Main article Requirements engineering Requirements engineering and software architecture can be seen as complementary approaches while software architecture targets the solution space or the how requirements engineering addresses the problem space or the what 43 Requirements engineering entails the elicitation negotiation specification validation documentation and management of requirements Both requirements engineering and software architecture revolve around stakeholder concerns needs and wishes There is considerable overlap between requirements engineering and software architecture as evidenced for example by a study into five industrial software architecture methods that concludes that the inputs goals constraints etc are usually ill defined and only get discovered or better understood as the architecture starts to emerge and that while most architectural concerns are expressed as requirements on the system they can also include mandated design decisions 25 In short required behavior impacts solution architecture which in turn may introduce new requirements 44 Approaches such as the Twin Peaks model 45 aim to exploit the synergistic relation between requirements and architecture Other types of architecture edit Main articles Computer architecture Systems architecture and Enterprise architecture Computer architecture Computer architecture targets the internal structure of a computer system in terms of collaborating hardware components such as the CPU or processor the bus and the memory Serverless architecture Serverless architecture is a cloud computing paradigm that is often misunderstood as being server free It essentially shifts server management responsibilities from developers to cloud service providers This allows businesses to run their backend code on cloud infrastructure eliminating the need for physical server management The event driven approach of serverless architecture relies on small task specific functions that are executed on demand These functions are known as Function as a Service FaaS and they offer cost efficiency through a pay as you go billing model and dynamic resource scaling based on application demand 46 better source needed Systems architecture The term systems architecture has originally been applied to the architecture of systems that consist of both hardware and software The main concern addressed by the systems architecture is then the integration of software and hardware in a complete correctly working device In another common much broader meaning the term applies to the architecture of any complex system which may be of a technical sociotechnical or social nature Enterprise architecture The goal of enterprise architecture is to translate business vision and strategy into effective enterprise Enterprise architecture frameworks such as TOGAF and the Zachman Framework usually distinguish between different enterprise architecture layers Although terminology differs from framework to framework many include at least a distinction between a business layer an application or information layer and a technology layer Enterprise architecture addresses among others the alignment between these layers usually in a top down approach See also editArchiMate Architectural pattern computer science Anti pattern Attribute driven design C4 model Computer architecture Distributed Data Management Architecture Distributed Relational Database Architecture Systems architecture Systems design Software Architecture Analysis Method Time triggered systemReferences edit a b c Clements Paul Felix Bachmann Len Bass David Garlan James Ivers Reed Little Paulo Merson Robert Nord Judith Stafford 2010 Documenting Software Architectures Views and Beyond Second Edition Boston Addison Wesley ISBN 978 0 321 55268 6 Software Architecture www sei cmu edu Retrieved 2018 07 23 a b c d Perry D E Wolf A L 1992 Foundations for the study of software architecture PDF ACM SIGSOFT Software Engineering Notes 17 4 40 CiteSeerX 10 1 1 40 5174 doi 10 1145 141874 141884 S2CID 628695 a b c d e f g h i j Bass Len Paul Clements Rick Kazman 2012 Software Architecture in Practice Third Edition Boston Addison Wesley ISBN 978 0 321 81573 6 SEI 2006 How do you define Software Architecture Retrieved 2012 09 12 Garlan amp Shaw 1994 An Introduction to Software Architecture PDF Retrieved 2012 09 13 a b Fowler Martin 2003 Design Who needs an architect IEEE Software 20 5 11 44 doi 10 1109 MS 2003 1231144 S2CID 356506 ISO IEC IEEE 42010 Defining architecture Iso architecture org Retrieved on 2013 07 21 a b Jansen A Bosch J 2005 Software Architecture as a Set of Architectural Design Decisions 5th Working IEEE IFIP Conference on Software Architecture WICSA 05 p 109 CiteSeerX 10 1 1 60 8680 doi 10 1109 WICSA 2005 61 ISBN 978 0 7695 2548 8 S2CID 13492610 Ali Babar Muhammad Dingsoyr Torgeir Lago Patricia van Vliet Hans 2009 Software Architecture Knowledge Management Dordrecht Heidelberg London New York Springer ISBN 978 3 642 02373 6 a b c George Fairbanks 2010 Just Enough Software Architecture Marshall amp Brainerd a b ISO IEC IEEE 2011 ISO IEC IEEE 42010 2011 Systems and software engineering Architecture description Retrieved 2012 09 12 Muller Gerrit August 20 2007 A Reference Architecture Primer PDF Gaudi site Archived PDF from the original on 2011 12 19 Retrieved November 13 2015 Angelov S Grefen P Greefhorst D 2009 A classification of software reference architectures Analyzing their success and effectiveness 2009 Joint Working IEEE IFIP Conference on Software Architecture amp European Conference on Software Architecture IEEE pp 141 150 doi 10 1109 WICSA 2009 5290800 ISBN 978 1 4244 4984 2 Retrieved 15 December 2023 Brooks Frederick P Jr 1975 The Mythical Man Month Essays on Software Engineering Addison Wesley ISBN 978 0 201 00650 6 Conway Melvin Conway s Law Mel Conway s Home Page Archived from the original on 2019 09 29 Retrieved 2019 09 29 a b Obbink H Kruchten P Kozaczynski W Postema H Ran A Dominick L Kazman R Hilliard R Tracz W Kahane E Feb 6 2002 Software Architecture Review and Assessment SARA Report PDF Retrieved November 1 2015 Poort Eltjo van Vliet Hans September 2012 RCDA Architecting as a risk and cost management discipline Journal of Systems and Software 85 9 1995 2013 doi 10 1016 j jss 2012 03 071 P Naur B Randell eds 1969 Software Engineering Report of a conference sponsored by the NATO Science Committee Garmisch Germany 7 11 Oct 1968 PDF Brussels NATO Scientific Affairs Division Archived PDF from the original on 2003 06 07 Retrieved 2012 11 16 P Kruchten H Obbink J Stafford 2006 The past present and future of software architecture IEEE Software 23 2 22 doi 10 1109 MS 2006 59 S2CID 2082927 University of Waterloo 2006 A Very Brief History of Computer Science Retrieved 2006 09 23 Introduction to the Special Issue on Software Architecture IEEE org 2006 doi 10 1109 TSE 1995 10003 Garlan amp Shaw 1994 An Introduction to Software Architecture PDF Retrieved 2006 09 25 a b Kruchten P 2008 What do software architects really do Journal of Systems and Software 81 12 2413 2416 doi 10 1016 j jss 2008 08 025 a b c Christine Hofmeister Philippe Kruchten Robert L Nord Henk Obbink Alexander Ran Pierre America 2007 A general model of software architecture design derived from five industrial approaches Journal of Systems and Software 80 1 106 126 doi 10 1016 j jss 2006 05 024 a b ISO IEC 2011 ISO IEC 25010 2011 Systems and software engineering Systems and software Quality Requirements and Evaluation SQuaRE System and software quality models Retrieved 2012 10 08 Osterwalder and Pigneur 2004 An Ontology for e Business Models PDF Value Creation from E Business Models pp 65 97 CiteSeerX 10 1 1 9 6922 doi 10 1016 B978 075066140 9 50006 0 ISBN 9780750661409 S2CID 14177438 Archived from the original PDF on 2018 11 17 Chen Lianping Ali Babar Muhammad Nuseibeh Bashar 2013 Characterizing Architecturally Significant Requirements IEEE Software 30 2 38 45 doi 10 1109 MS 2012 174 hdl 10344 3061 S2CID 17399565 Woods E 2012 Industrial architectural assessment using TARA Journal of Systems and Software 85 9 2034 2047 doi 10 1016 j jss 2012 04 055 S2CID 179244 Maranzano J F Rozsypal S A Zimmerman G H Warnken G W Wirth P E Weiss D M 2005 Architecture Reviews Practice and Experience IEEE Software 22 2 34 doi 10 1109 MS 2005 28 S2CID 11697335 Babar M A Dingsoyr T Lago P Vliet H van 2009 Software Architecture Knowledge Management Theory and Practice eds First Edition Springer ISBN 978 3 642 02373 6 Tang A Han J Vasa R 2009 Software Architecture Design Reasoning A Case for Improved Methodology Support IEEE Software 26 2 43 doi 10 1109 MS 2009 46 hdl 1959 3 51601 S2CID 12230032 Kruchten Philippe 1995 Architectural Blueprints The 4 1 View Model of Software Architecture PDF IEEE Software 12 6 42 50 arXiv 2006 04975 doi 10 1109 52 469759 S2CID 219558624 a b Shaw Mary Garlan David 1996 Software architecture perspectives on an emerging discipline Prentice Hall ISBN 978 0 13 182957 2 UCI Software Architecture Research UCI Software Architecture Research Architectural Styles Isr uci edu Retrieved on 2013 07 21 a b Chapter 3 Architectural Patterns and Styles Msdn microsoft com Retrieved on 2013 07 21 Boehm Barry Turner Richard 2004 Balancing Agility and Discipline Addison Wesley ISBN 978 0 321 18612 6 a b c Li Ruiyin Liang Peng Soliman Mohamed Avgeriou Paris 2022 Understanding software architecture erosion A systematic mapping study Journal of Software Evolution and Process 34 3 e2423 arXiv 2112 10934 doi 10 1002 smr 2423 Li Ruiyin Liang Peng Soliman Mohamed Avgeriou Paris 2021 Understanding architecture erosion The practitioners perceptive The 29th IEEE ACM International Conference on Program Comprehension ICPC pp 311 322 doi 10 1109 icpc52881 2021 00037 van Gurp J and Bosch J 2002 Design erosion Problems and causes Journal of Systems and Software 61 2 105 119 Lungu M Software architecture recovery University of Lugano 2008 http www slideshare net mircea lungu software architecture recovery in five questions presentation a b Amnon H Eden Rick Kazman 2003 Architecture Design Implementation PDF Archived from the original PDF on 2007 09 28 C Shekaran D Garlan M Jackson N R Mead C Potts H B Reubenstein 1994 The role of software architecture in requirements engineering Proceedings of IEEE International Conference on Requirements Engineering pp 239 245 doi 10 1109 ICRE 1994 292379 ISBN 978 0 8186 5480 0 S2CID 3129363 Remco C de Boer Hans van Vliet 2009 On the similarity between requirements and architecture Journal of Systems and Software 82 3 544 550 CiteSeerX 10 1 1 415 6023 doi 10 1016 j jss 2008 11 185 Bashar Nuseibeh 2001 Weaving together requirements and architectures PDF Computer 34 3 115 119 doi 10 1109 2 910904 Archived PDF from the original on 2012 09 07 Company DashDevs FinTech Software Development How to Use Serverless Architecture DashDevs How to Use Serverless Architecture DashDevs Retrieved 2023 08 28 Further reading editRichards Mark 2020 Fundamentals of Software Architecture An Engineering Approach O Reilly Media ISBN 9781492043454 Len Bass 2012 Software Architecture in Practice 3rd ed Addison Wesley Professional ISBN 9780321815736 This book covers the fundamental concepts of the discipline The theme is centered on achieving quality attributes of a system Clements Paul 2010 Documenting Software Architectures Views and Beyond 2nd ed Addison Wesley Professional ISBN 9780321552686 This book describes what software architecture is and shows how to document it in multiple views using UML and other notations It also explains how to complement the architecture views with behavior software interface and rationale documentation Accompanying the book is a wiki that contains an example of software architecture documentation Bell Michael 2008 Bell Michael ed Service Oriented Modeling Service Analysis Design and Architecture Wiley doi 10 1002 9781119198864 ISBN 9780470255704 Shan Tony Hua Winnie October 2006 Solution Architecting Mechanism 2006 10th IEEE International Enterprise Distributed Object Computing Conference EDOC 06 pp 23 32 doi 10 1109 EDOC 2006 54 ISBN 978 0 7695 2558 7 S2CID 8361936 Garzas Javier Piattini Mario 2005 An ontology for micro architectural design knowledge IEEE Software 22 2 28 33 doi 10 1109 MS 2005 26 S2CID 17639072 Fowler Martin September 2003 Who Needs an Architect PDF IEEE Software 20 5 doi 10 1109 MS 2003 1231144 S2CID 356506 Kazman Rick May 2003 Architecture Design Implementation PDF Software Engineering Institute Archived PDF from the original on 2015 09 21 On the distinction between architectural design and detailed design Kruchten Philippe 1995 Architectural Blueprints The 4 1 View Model of Software Architecture PDF IEEE Software 12 6 42 50 arXiv 2006 04975 doi 10 1109 52 469759 S2CID 219558624 Archived PDF from the original on 2006 06 13 Pautasso Cesare 2020 Software Architecture visual lecture notes LeanPub p 689 External links edit nbsp Wikimedia Commons has media related to Software architecture nbsp Wikiquote has quotations related to Software architecture Explanation on IBM Developerworks Collection of software architecture definitions at Software Engineering Institute SEI Carnegie Mellon University CMU International Association of IT Architects IASA Global formerly known as the International Association for Software Architects IASA SoftwareArchitecturePortal org website of IFIP Working Group 2 10 on Software Architecture SoftwareArchitectures com an independent resource of information on the discipline Software Architecture chapter 1 of Roy Fielding s REST dissertation When Good Architecture Goes Bad The Spiral Architecture Driven Development the SDLC based on the Spiral model aims to reduce the risks of ineffective architecture Software Architecture Real Life Case Studies Retrieved from https en wikipedia org w index php title Software architecture amp oldid 1223595610, wikipedia, wiki, book, books, library,

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