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Architecture

There are many different views that are summarized by the term architecture. First, we will introduce the key principles and architecture principles of devonfw. Then, we will go into details of the the architecture of an application.

Key Principles

For devonfw we follow these fundamental key principles for all decisions about architecture, design, or choosing standards, libraries, and frameworks:

  • KISS
    Keep it small and simple

  • Open
    Commitment to open standards and solutions (no required dependencies to commercial or vendor-specific standards or solutions)

  • Patterns
    We concentrate on providing patterns, best-practices and examples rather than writing framework code.

  • Solid
    We pick solutions that are established and have been proven to be solid and robust in real-live (business) projects.

Architecture Principles

Additionally we define the following principles that our architecture is based on:

  • Component Oriented Design
    We follow a strictly component oriented design to address the following sub-principles:

    • Separation of Concerns

    • Reusability and avoiding redundant code

    • Information Hiding via component API and its exchangeable implementation treated as secret.

    • Design by Contract for self-contained, descriptive, and stable component APIs.

    • Layering as well as separation of business logic from technical code for better maintenance.

    • Data Sovereignty (and high cohesion with low coupling) says that a component is responsible for its data and changes to this data shall only happen via the component. Otherwise, maintenance problems will arise to ensure that data remains consistent. Therefore, interfaces of a component that may be used by other components are designed call-by-value and not call-by-reference.

  • Homogeneity
    Solve similar problems in similar ways and establish a uniform code-style.

As an architect you should be prepared for the future by reading the TechnoVision.

Application Architecture

For the architecture of an application we distinguish the following views:

  • The Business Architecture describes an application from the business perspective. It divides the application into business components and with full abstraction of technical aspects.

  • The Technical Architecture describes an application from the technical implementation perspective. It divides the application into technical layers and defines which technical products and frameworks are used to support these layers.

  • The Infrastructure Architecture describes an application from the operational infrastructure perspective. It defines the nodes used to run the application including clustering, load-balancing and networking. This view is not explored further in this guide.

Business Architecture

The business architecture divides the application into business components. A business component has a well-defined responsibility that it encapsulates. All aspects related to that responsibility have to be implemented within that business component. Further, the business architecture defines the dependencies between the business components. These dependencies need to be free of cycles. A business component exports its functionality via well-defined interfaces as a self-contained API. A business component may use another business component via its API and compliant with the dependencies defined by the business architecture.

As the business domain and logic of an application can be totally different, the devonfw can not define a standardized business architecture. Depending on the business domain it has to be defined from scratch or from a domain reference architecture template. For very small systems it may be suitable to define just a single business component containing all the code.

Technical Architecture

The technical architecture divides the application into technical layers based on the multilayered architecture. A layer is a unit of code with the same category such as a service or presentation logic. So, a layer is often supported by a technical framework. Each business component can therefore be split into component parts for each layer. However, a business component may not have component parts for every layer (e.g. only a presentation part that utilized logic from other components).

An overview of the technical reference architecture of the devonfw is given by figure "Technical Reference Architecture". It defines the following layers visualized as horizontal boxes:

Also, you can see the (business) components as vertical boxes (e.g. A and X) and how they are composed out of component parts each one assigned to one of the technical layers.

Further, there are technical components for cross-cutting aspects grouped by the gray box on the left. Here is a complete list:

devonfw architecture blueprint
Figure 1. Technical Reference Architecture

Please click on the architecture image to open it as SVG and click on the layers and cross-cutting topics to open the according documentation guide.

We reflect this architecture in our code as described in our coding conventions allowing a traceability of business components, use-cases, layers, etc. into the code and giving developers a sound orientation within the project.

Further, the architecture diagram shows the allowed dependencies illustrated by the dark green connectors. Within a business component a component part can call the next component part on the layer directly below via a dependency on its API (vertical connectors). While this is natural and obvious, it is generally forbidden to have dependencies upwards the layers or to skip a layer by a direct dependency on a component part two or more layers below. The general dependencies allowed between business components are defined by the business architecture. In our reference architecture diagram we assume that the business component A1 is allowed to depend on component A2. Therefore, a use-case within the logic component part of A1 is allowed to call a use-case from A2 via a dependency on the component API. The same applies for dialogs on the client layer. This is illustrated by the horizontal connectors. Please note that persistence entities are part of the API of the data-access component part so only the logic component part of the same business component may depend on them.

The technical architecture has to address non-functional requirements:

  • scalability
    is established by keeping state in the client and making the server state-less (except for login session). Via load-balancers new server nodes can be added to improve performance (horizontal scaling).

  • availability and reliability
    are addressed by clustering with redundant nodes avoiding any single-point-of failure. If one node fails the system is still available. Further, the software has to be robust so there are no dead-locks or other bad effects that can make the system unavailable or not reliable.

  • security
    is archived in the devonfw by the right templates and best-practices that avoid vulnerabilities. See security guidelines for further details.

  • performance
    is obtained by choosing the right products and proper configurations. While the actual implementation of the application matters for performance a proper design is important as it is the key to allow performance-optimizations (see e.g. caching).

Technology Stack

The technology stack of the devonfw is illustrated by the following table.

Table 1. Technology Stack of devonfw
Topic Detail Standard Suggested implementation

runtime

language & VM

Java

Oracle JDK

runtime

servlet-container

JEE

tomcat

component management

dependency injection

JSR330 & JSR250

spring

configuration

framework

-

spring-boot

persistence

OR-mapper

JPA

hibernate

batch

framework

JSR352

spring-batch

service

SOAP services

JAX-WS

CXF

service

REST services

JAX-RS

CXF

logging

framework

slf4j

logback

validation

framework

beanvalidation/JSR303

hibernate-validator

security

Authentication & Authorization

JAAS

spring-security

monitoring

framework

JMX

spring

monitoring

HTTP Bridge

HTTP & JSON

jolokia

AOP

framework

dynamic proxies

spring AOP