I have 2 years in the IT industry,i love to read a lot ,but when i go deep in some subjects i see a lot of contradiction in somes articles,forum or terms that are used interchangeable.
I understand the difference between Soap and Rest.
When we want to communicate between backends, we can use either of these 2 approaches, each with its advantages and disadvantages.
Situation :
If i have an application, which can be monolithic or not, where I have a backend and I will only have a front end that consumes it. Usually we create a Rest Api so that our front end can consume it. But we will never think about exposing our backend with Soap.(Lot of reasons)
Questions:
1 -Is it okay if I say that Rest , in addition to allowing us to exchange information between application and application (backend to backend ), is it also useful when exposing services for our front end? And SOAP is only useful for Server - Server communication?
2 -And finally, if I expose a backend only for a front end, it is ok to say that we expose a web service or conceptually we say that it is a backend for frontend ?
Question 1: No the First question is wrong Assumption. We can say that in SOAP, XML is the only means of communication, while in Rest, the accepted means is JSON, while there are other formats like XML, JSON, PDF, HTML etc. and Ofcourse, XML can be converted back from server into UI Language and XML Request deciphered at Server for a Response. So, its not Ok to say that SOAP is only for Server - Server Communication.
2. No, when you have typically exposed backend only for consumption by a Front end, you can typically say that it is a backend for numerous front end client requests. But IMO, Backend for a front end is a monolithic webapplication, both bundled in WAR. so in that sense, any UI Request can request response from the Back end web service. Hope i am able to clear your understanding about web services.
I see that in your question there are actually 4 embedded independent topics. And probably because they are always used in conjunction it is sometimes tough to understand.
I will give a short answer first:
REST and SOAP both can be used for Client-Server and Server-Server integrations. But the choice will be dependent on the questions like where you want server-side UI technology/client-side UI technology or is it a single page application/portal technology, etc.
If you expose a single-backend for a single-frontend it's technically a BFF although the term BFF is used only in the case where you have separate-backends for each type of frontend application. e.g. one for mobile, one for web, one for IoT devices, etc.
The long answer is to clarify the 4 principles. Let me give a try at this by separating the topics into the below four headings:
1. Backend(Business Layer) vs Backend for frontend(BFF)
In classical 3-tier architecture (UI-Business Layer-Database) world, the middle-layer that consists of the business and integration logic is mostly referred to as backend/business layer.
This layer can be separated from the UI/Frontend using multiple different options like APIs(REST/SOAP), RPC, Servlet Technology, etc. The limitation with this 3-tier architecture is that, it is still tightly coupled to the type of users and use-cases are limited to web/browser based. It is not a good choice when you want to reuse the business-layer for both web and mobile as the mobile applications are required to be light-weight by principle.
That's where we lean on to multi-tier architecture with Backend For Frontend(BFF) as a savior. It's just a methodology to segregate the business-layers based on consumers.
2. Monolith vs SOA vs Microservices(Optimized SOA)
In a monolith world all the code components mostly UI and Business Layer sits in a tightly coupled fashion. The simplest example would be a Java Servlet Pages(JSP) application with Java as Business Layer. These are typically server-side UI technologies.
In Service Oriented Architecture(SOA), the usecases revolve around leveraging reusable business layer functions aka services. Here one would have to deal with UI-Server, Inter-Service and Server-Server integration scenarios. It's heavily service dependent, meaning it's like a spider-web of dependent applications.
The Microservices is an extension of SOA, but the approach is to keep a resource in focus instead of services to reduce the spider-web dependencies. Hence, self-sufficient and standalone service-clusters are the base of micro-services architecture.
3. SOAP vs REST Webservices
SOAP stands for Simple Object Access Protocol, typically used by the business-layer to provide user-defined methods/services to manipulate an object. For example look at the names of the services for accessing a book collection
To get a book getABook()
Get the whole list of books listAllBooks()
Find a book by name searchABook(String name)
Update a book's details updateABookDetails()
On the other hand, REST is representational state transfer which transfers the state of a web-resource to the client using underlying existing HTTP methods. So the above services for accessing a book collection would look like
To get a book /book(HTTP GET)
Get the whole list of books /books(HTTP GET)
Find a book by name /book?name={search}(HTTP GET)
Update a book's details /book/{bookId}(HTTP PATCH/PUT)
4. How to make a correct choice of architecture?
Spot the diversity of the application user groups and usages: This will help to understand the platform(web/mobile/IoT/etc), nature of the application and session-management.
Determine the estimated/required throughput: This will help you to understand the scalability requirements.
How frequently and who will be maintaining the application: This will help to gauge the application and technology complexity, deployment cycles, deployment strategy, appetite for downtime, etc.
In conclusion, always follow the divine rule of KISS: Keep it simple, stupid.
1.)
A webapplication is for H2M communication a webservice is for M2M communication through the web. The interface of the service is more standardized, more structured, so machines can easily use it and parse the messages.
I don't think it matters where your service consumer is, it can run in a browser or it can run on the server. As long as it can communicate with the service on a relative safe channel it is ok.
You design a service usually to decouple it from multiple different consumers, so you don't have to deal with the consumer implementations. This makes sense usually when you have potentially unknown consumers programmed usually by 3rd party programmers you don't even know or want to know about. You version the service or at least the messages to stay compatible with old consumers.
If you have only a single consumer developed by you, then it might be too much extra effort to maintain a service with a quasi-standard interface. You can easily change the code of the consumer when you change the interface of the service, so thinking about interface design, standardization, backward compatibility, etc. does not make much sense. Though you can still use REST or SOAP ad hoc without much design. In this case having a RESTish CRUD API without hypermedia is a better choice I think.
2.)
I think both are good, I would say backend in your scenario.
Related
I am unsure how to make use of event-driven architecture in real-world scenarios. Let's say there is a route planning platform consisting of the following back-end services:
user-service (manages user data and roles)
map-data-service (roads & addresses, only modified by admins)
planning-tasks-service
(accepts new route planning tasks, keeps track of background tasks, stores results)
The public website will usually request data from all 3 of those services. map-data-service needs information about user-roles on a data change request. planning-tasks-service needs information about users, as well as about map-data to validate new tasks.
Right now those services would just make a sync request to each other to get the needed data. What would be the best way to translate this basic structure into an event-driven architecture? Can dependencies be reduced by making use of events? How will the public website get the needed data?
Cosmin is 100% correct in that you need something to do some orchestration.
One approach to take, if you have a client that needs data from multiple services, is the Experience API approach.
Clients call the experience API, which performs the orchestration - pulling data from different sources and providing it back to the client. The design of the experience API is heavily, and deliberately, biased towards what the client needs.
Based on the details you've said so far, I can't see anything that cries out for event-based architecture. The communication between the client and ExpAPI can be a mix of sync and async, as can the ExpAPI to [Services] communication.
And for what it's worth, putting all of that on API gateway is not a bad idea, in that they are designed to host API's and therefore provide the desirable controls and observability for managing them.
Update based on OP Comment
I was really interested in how an event-driven architecture could
reduce dependencies between my microservices, as it is often stated
Having components (or systems) talk via events is sort-of the asynchronous equivalent of Inversion of Control, in that the event consumers are not tightly-coupled to the thing that emits the events. That's how the dependencies are reduced.
One thing you could do would be to do a little side-project just as a learning exercise - take a snapshot of your code and do a rough-n-ready conversion to event-based and just see how that went - not so much as an attempt to event-a-cise your solution but to see what putting events into a real-world solution looks like. If you have the time, of course.
The missing piece in your architecture is the API Gateway, which should be the only entry-point in your system, used by the public website directly.
The API Gateway would play the role of an orchestrator, which decides to which services to route the request, and also it assembles the final response needed by the frontend.
For scalability purposes, the communication between the API Gateway and individual microservices should be done asynchronously through an event-bus (or message queue).
However, the most important step in creating a scalable event-driven architecture which leverages microservices, is to properly define the bounded contexts of your system and understand the boundaries of each functionality.
More details about this architecture can be found here
Event storming is the first thing you need to do to identify domain events(a change in state in your system). For example, 'userCreated', 'userModified', 'locatinCreated', 'routeCreated', 'routeCompleted' etc. Then you can define topics that manage these events. Interested parties can consume these events by subscribing to published events(via topics/channel) and then act accordingly. Implementation of an event-driven architecture is often composed of loosely coupled microservices that communicate asynchronously through a message broker like Apache Kafka. Free EDA book is an excellent resource to know most of the things in EDA.
Tutorial: Even-driven-architecture pattern
I am learning about microservices and I don't understand what the real difference
between creating a REST API and creating microservices?
I’m working in Go, but my question applies over all languages.
The Microservices approach is about breaking your system ("pile of code") into many small services, each typically has its own:
Clear business-related responsibility
Running process
Database
Code version control (e.g. git) repository
API (the protocol how other services / clients will contact the Microservice)
UI
The services themselves are kept small so as your system grow, there are more services - rather than larger services.
Microservices can use REST, RPC, or any other method to communicate with one another, so REST or an API is really orthogonal to the topic of microservices...
Reference: What is an API? In English, please.
API = Application Programming Interface
Microservices = an architecture
In short
Microservice should expose a well-defined API.
Microservice is the way you may want to architect your solution
API is what your consumers see.
You can expose API without microservices in the backend (in fact, most non-training scenarios don't require microservices).
You may want to read http://samnewman.io/books/building_microservices/ before you decide on using microservices (unless this is for training purposes).
Microservice is well defined when you are following SOC - seperation of Concern on the entity/domain level ,where each entity / domain are independent of any other service.
for example user service will only be responsible for storing, updating and deleting user related informations.
Microservice backend and frontend microservice can further be splitted in 2 parts
frontend microservice which exposes rest endpoint just like Web API
backend microservice which actually perform all the operations.
Rest API is more of endpoints exposed to outer world and can be used with microservices as well, as explained above.
The majority of the answers is based on the old-school understanding of API as a programmatic interface. Nowadays, this meaning is melted and start confusing people becuase some developers started (for simplicit or by mistake) interpred the API of an application as the application per se. In such case, it is impossible to distinguish between the modern API and Microservices. Nonetheless, we can say that an API-application can comprise many Microservices, the most of which interact within the application via Microservice's APIs while others may expose their APIs as Applications's APIs. Also, a Microservice (as a service) may not include other Microservices (services), but may orchestrate a composition of Microservices via API-bases invocations. Applications may contain Microservices but, in the best practices, may not contain other Applications.
Microservices
A microservice architecture is about slicing an application logic into small pieces or "components" that can act between them and/or be exposed through an API.
API
A (web) application need to design the business logic with all set of object entities (model) and possible operations on them.
An (Application Programming Interface][https://en.wikipedia.org/wiki/Application_programming_interface) is a way of making the requests to an application by exposing specific entry-points that are in charge of invoking the appropriate application operations.
ReST(ful) APIs
("ReST" as in Representational State Transfer) are APIs complying with at least these 5 constraints:
User-interface is distinct from data storage and manipulation (Client-Server architecture)
No client context is stored on the server ("stateless")
Server responses must, implicitly or explicitly, define themselves as cacheable or not
Client does not have to be aware of the layers between him and the server
Response/request messages must be: be self-descriptive; allow to identify a resource; use representations allowing to manipulate the resources; announce available actions and resources ("Uniform interface").
"The real difference"
So, while these notions are obviously related, they are clearly distinct concepts:
Being ReSTful or not, an API exposes operations provided by a server that might (but not necessarily) be shelled into smaller components (microservices).
Also, while a typical web (ReST)API uses the HTTP protocol between the client and the server, components within a microservice architecture might communicate using other protocol(s) (e.g. WAMP, AMQP, JSON-RPC, XML-RPC, SOAP, ...)
In layman's term, if you have a web API server and you split them into several independent mini servers, use a proxy-server and load-balancer to clusterize them, and (optionally, give each a separate database entity), that is a microservice architecture.
I thought I knew what REST/"RESTFul", restfulservices, webservices, SOA and microservices were but I came across so many different definitions that I reached the conclusion that those terms are overused, misused , or simply badly defined.
I hope to have a clear understanding of what the aforementioned terms represent, their concrete definition , their commonality and differences, advantages vs disadvantages, and most importantly the bottom line - the most important things to remember in order to use those terms appropriately.
Disclaimer: most of this post is subjective. No attempt has been made here to strictly define anything, just trying to contextualize and give a global overview of the concepts and how they relate to each other.
I thought I knew what REST/"RESTFul", restfulservices, webservices,
SOA and microservices
I'd say that all these terms fall into the umbrella of Service Oriented Architectures (SOA). Web services is a SOA using web-related technologies. REST and its subset RESTful are a set of practices to implement web services. Finally, microservices are a new set of SOA practices.
I hope to have a clear understanding of what the aforementioned terms
represent
I'll try to address this point, but using informal definitions and without entering into advantages and disadvantages. That'd be way too long and I think the biggest points should be obvious from the explanations.
SOA
I think the name is self-explanatory in this case: SOA -- which stands for Service Oriented Architecture -- refers to architectures designed with a focus on services. Now, the tricky part here is what you may or may not consider a service and that is a whole different topic.
Web services
This accounts for the subset of SOA using web-related technologies. This typically involves HTTP and XML but it could also use FTP. I think the term web here is quite vague as it generally refers to standard Internet technologies.
REST(ful)
REST is a subset of web services -- and hence a SOA -- that revolves around using HTTP for communication. There are a certain set of common practices such as a certain given relevance to URLs.
About 10 years ago when I was introduced to REST, RESTful was presented to me as a more strict REST implementation where a resource would have a unique URI and it would be managed through CRUD operations mapped to HTTP verbs -- Create = POST, Read = GET, Update = PUT, Delete = Delete.
Updating user information through a HTTP GET or POST request o a /users/1/update URL would be perfectly valid in REST, but it would not be RESTful. For the latter, the approach would be to use an HTTP PUT or PATCH over /users/1 (which would also be the URL for the rest of the operations, simply varying the HTTP verb).
I find that this distinctions has become blurred over the years. However, it still stands that RESTful is a more strict subset of REST. (The exact requirements may be debatable.)
EDIT - A more formal definition:
REST stands for Representational State Transfer and was presented by Roy Fielding in his Ph.D. thesis as an architectural style for distributed hypermedia systems. The emphasis goes into the hypermedia and self-containment decoupling the client from most beforehand knowledge among others. A website is an example: it consists on a single URI (the website root) and a media type (HTML) through which the server offers all the information a client needs regarding resources and all possible interactions.
I'd say 99% people talking about REST really mean RPC or HTTP-based interfaces: using HTTP endpoints to invoke certain actions or query data. Fielding himself has tried to clarify this. Any API formed by a set of predefined URLs expecting certain HTTP verbs and some parameters falls into that 99%. So does my description above. However, I doubt the term itself can ever survive its misuse and I think we must accept its new meaning.
Microservices
This is the more recent term; it promotes implementing applications as a set of simple independently deployable services. This contrasts with the classic approach of SOA architectures as a set of quite complex services used to build complex systems, tipically involving an enterprise service bus. However, it is important to note that although typically SOA gets associated with such systems, it is a broader term and indeed, microservices are also a subset of SOA.
Microservices usually appear hand-by-hand with modern JavaScript full-stacks -- i.e. using JavaScript for all the vertical components, from the server up to user interface. Arguably this is so because using these JavaScripts full-stacks may speed up development thanks to the simplified integration. These stacks, and hence microservices implemented using them, are usually architected through REST but from a theoretical point of view, there is nothing preventing you from using a different approach to the same philosophy.
Let me introduce you a taxonomic view of those term:
Microservices
are a subtype of services specialized by minimal responsibility.
Webservices
are a subtype of services as well, specialized by the type of service they provide wich fall under web requirements and needs.
SOA
is a subtype of architectures and hence a structural view of some components and their relationships, where happens to be services and communications between those services respectively.
rest
is a subtype of communication, underlying http protocol.
restful
is a subtype of architectures (a structural view of some components and their relationships) where specialized by relationships among components restricted to be rest communications.
I have read articles about the differences between SOAP and REST as a web service communication protocol, but I think that the biggest advantages for REST over SOAP are:
REST is more dynamic, no need to create and update UDDI(Universal Description, Discovery, and Integration).
REST is not restricted to only XML format. RESTful web services can send plain text/JSON/XML.
But SOAP is more standardized (E.g.: security).
So, am I correct in these points?
Unfortunately, there are a lot of misinformation and misconceptions around REST. Not only your question and the answer by #cmd reflect those, but most of the questions and answers related to the subject on Stack Overflow.
SOAP and REST can't be compared directly, since the first is a protocol (or at least tries to be) and the second is an architectural style. This is probably one of the sources of confusion around it, since people tend to call REST any HTTP API that isn't SOAP.
Pushing things a little and trying to establish a comparison, the main difference between SOAP and REST is the degree of coupling between client and server implementations. A SOAP client works like a custom desktop application, tightly coupled to the server. There's a rigid contract between client and server, and everything is expected to break if either side changes anything. You need constant updates following any change, but it's easier to ascertain if the contract is being followed.
A REST client is more like a browser. It's a generic client that knows how to use a protocol and standardized methods, and an application has to fit inside that. You don't violate the protocol standards by creating extra methods, you leverage on the standard methods and create the actions with them on your media type. If done right, there's less coupling, and changes can be dealt with more gracefully. A client is supposed to enter a REST service with zero knowledge of the API, except for the entry point and the media type. In SOAP, the client needs previous knowledge on everything it will be using, or it won't even begin the interaction. Additionally, a REST client can be extended by code-on-demand supplied by the server itself, the classical example being JavaScript code used to drive the interaction with another service on the client-side.
I think these are the crucial points to understand what REST is about, and how it differs from SOAP:
REST is protocol independent. It's not coupled to HTTP. Pretty much like you can follow an ftp link on a website, a REST application can use any protocol for which there is a standardized URI scheme.
REST is not a mapping of CRUD to HTTP methods. Read this answer for a detailed explanation on that.
REST is as standardized as the parts you're using. Security and authentication in HTTP are standardized, so that's what you use when doing REST over HTTP.
REST is not REST without hypermedia and HATEOAS. This means that a client only knows the entry point URI and the resources are supposed to return links the client should follow. Those fancy documentation generators that give URI patterns for everything you can do in a REST API miss the point completely. They are not only documenting something that's supposed to be following the standard, but when you do that, you're coupling the client to one particular moment in the evolution of the API, and any changes on the API have to be documented and applied, or it will break.
REST is the architectural style of the web itself. When you enter Stack Overflow, you know what a User, a Question and an Answer are, you know the media types, and the website provides you with the links to them. A REST API has to do the same. If we designed the web the way people think REST should be done, instead of having a home page with links to Questions and Answers, we'd have a static documentation explaining that in order to view a question, you have to take the URI stackoverflow.com/questions/<id>, replace id with the Question.id and paste that on your browser. That's nonsense, but that's what many people think REST is.
This last point can't be emphasized enough. If your clients are building URIs from templates in documentation and not getting links in the resource representations, that's not REST. Roy Fielding, the author of REST, made it clear on this blog post: REST APIs must be hypertext-driven.
With the above in mind, you'll realize that while REST might not be restricted to XML, to do it correctly with any other format you'll have to design and standardize some format for your links. Hyperlinks are standard in XML, but not in JSON. There are draft standards for JSON, like HAL.
Finally, REST isn't for everyone, and a proof of that is how most people solve their problems very well with the HTTP APIs they mistakenly called REST and never venture beyond that. REST is hard to do sometimes, especially in the beginning, but it pays over time with easier evolution on the server side, and client's resilience to changes. If you need something done quickly and easily, don't bother about getting REST right. It's probably not what you're looking for. If you need something that will have to stay online for years or even decades, then REST is for you.
REST vs SOAP is not the right question to ask.
REST, unlike SOAP is not a protocol.
REST is an architectural style and a design for network-based software architectures.
REST concepts are referred to as resources. A representation of a resource must be stateless. It is represented via some media type. Some examples of media types include XML, JSON, and RDF. Resources are manipulated by components. Components request and manipulate resources via a standard uniform interface. In the case of HTTP, this interface consists of standard HTTP ops e.g. GET, PUT, POST, DELETE.
#Abdulaziz's question does illuminate the fact that REST and HTTP are often used in tandem. This is primarily due to the simplicity of HTTP and its very natural mapping to RESTful principles.
Fundamental REST Principles
Client-Server Communication
Client-server architectures have a very distinct separation of concerns. All applications built in the RESTful style must also be client-server in principle.
Stateless
Each client request to the server requires that its state be fully represented. The server must be able to completely understand the client request without using any server context or server session state. It follows that all state must be kept on the client.
Cacheable
Cache constraints may be used, thus enabling response data to be marked as cacheable or not-cacheable. Any data marked as cacheable may be reused as the response to the same subsequent request.
Uniform Interface
All components must interact through a single uniform interface. Because all component interaction occurs via this interface, interaction with different services is very simple. The interface is the same! This also means that implementation changes can be made in isolation. Such changes, will not affect fundamental component interaction because the uniform interface is always unchanged. One disadvantage is that you are stuck with the interface. If an optimization could be provided to a specific service by changing the interface, you are out of luck as REST prohibits this. On the bright side, however, REST is optimized for the web, hence incredible popularity of REST over HTTP!
The above concepts represent defining characteristics of REST and differentiate the REST architecture from other architectures like web services. It is useful to note that a REST service is a web service, but a web service is not necessarily a REST service.
See this blog post on REST Design Principles for more details on REST and the above stated bullets.
EDIT: update content based on comments
SOAP (Simple Object Access Protocol) and REST (Representation State Transfer) both are beautiful in their way. So I am not comparing them. Instead, I am trying to depict the picture, when I preferred to use REST and when SOAP.
What is payload?
When data is sent over the Internet, each unit transmitted includes both header information and the actual data being sent. The header identifies the source and destination of the packet, while the actual data is referred to as the payload. In general, the payload is the data that is carried on behalf of an application and the data received by the destination system.
Now, for example, I have to send a Telegram and we all know that the cost of the telegram will depend on some words.
So tell me among below mentioned these two messages, which one is cheaper to send?
<name>Arin</name>
or
"name": "Arin"
I know your answer will be the second one although both representing the same message second one is cheaper regarding cost.
So I am trying to say that, sending data over the network in JSON format is cheaper than sending it in XML format regarding payload.
Here is the first benefit or advantages of REST over SOAP. SOAP only support XML, but REST supports different format like text, JSON, XML, etc. And we already know, if we use Json then definitely we will be in better place regarding payload.
Now, SOAP supports the only XML, but it also has its advantages.
Really! How?
SOAP relies on XML in three ways
Envelope – that defines what is in the message and how to process it.
A set of encoding rules for data types, and finally the layout of the procedure calls and responses gathered.
This envelope is sent via a transport (HTTP/HTTPS), and an RPC (Remote Procedure Call) is executed, and the envelope is returned with information in an XML formatted document.
The important point is that one of the advantages of SOAP is the use of the “generic” transport but REST uses HTTP/HTTPS. SOAP can use almost any transport to send the request but REST cannot. So here we got an advantage of using SOAP.
As I already mentioned in above paragraph “REST uses HTTP/HTTPS”, so go a bit deeper on these words.
When we are talking about REST over HTTP, all security measures applied HTTP are inherited, and this is known as transport level security and it secures messages only while it is inside the wire but once you delivered it on the other side you don’t know how many stages it will have to go through before reaching the real point where the data will be processed. And of course, all those stages could use something different than HTTP.So Rest is not safer completely, right?
But SOAP supports SSL just like REST additionally it also supports WS-Security which adds some enterprise security features. WS-Security offers protection from the creation of the message to it’s consumption. So for transport level security whatever loophole we found that can be prevented using WS-Security.
Apart from that, as REST is limited by it's HTTP protocol so it’s transaction support is neither ACID compliant nor can provide two-phase commit across distributed transnational resources.
But SOAP has comprehensive support for both ACID based transaction management for short-lived transactions and compensation based transaction management for long-running transactions. It also supports two-phase commit across distributed resources.
I am not drawing any conclusion, but I will prefer SOAP-based web service while security, transaction, etc. are the main concerns.
Here is the "The Java EE 6 Tutorial" where they have said A RESTful design may be appropriate when the following conditions are met. Have a look.
Hope you enjoyed reading my answer.
REST(REpresentational State Transfer)
REpresentational State of an Object is Transferred is REST i.e. we don't send Object, we send state of Object.
REST is an architectural style. It doesn’t define so many standards like SOAP. REST is for exposing Public APIs(i.e. Facebook API, Google Maps API) over the internet to handle CRUD operations on data. REST is focused on accessing named resources through a single consistent interface.
SOAP(Simple Object Access Protocol)
SOAP brings its own protocol and focuses on exposing pieces of application logic (not data) as services. SOAP exposes operations. SOAP is focused on accessing named operations, each operation implement some business logic. Though SOAP is commonly referred to as web services this is misnomer. SOAP has a very little if anything to do with the Web. REST provides true Web services based on URIs and HTTP.
Why REST?
Since REST uses standard HTTP it is much simpler in just about ever way.
REST is easier to implement, requires less bandwidth and resources.
REST permits many different data formats where as SOAP only permits XML.
REST allows better support for browser clients due to its support for JSON.
REST has better performance and scalability. REST reads can be cached, SOAP based reads cannot be cached.
If security is not a major concern and we have limited resources. Or we want to create an API that will be easily used by other developers publicly then we should go with REST.
If we need Stateless CRUD operations then go with REST.
REST is commonly used in social media, web chat, mobile services and Public APIs like Google Maps.
RESTful service return various MediaTypes for the same resource, depending on the request header parameter "Accept" as application/xml or application/json for POST and /user/1234.json or GET /user/1234.xml for GET.
REST services are meant to be called by the client-side application and not the end user directly.
ST in REST comes from State Transfer. You transfer the state around instead of having the server store it, this makes REST services scalable.
Why SOAP?
SOAP is not very easy to implement and requires more bandwidth and resources.
SOAP message request is processed slower as compared to REST and it does not use web caching mechanism.
WS-Security: While SOAP supports SSL (just like REST) it also supports WS-Security which adds some enterprise security features.
WS-AtomicTransaction: Need ACID Transactions over a service, you’re going to need SOAP.
WS-ReliableMessaging: If your application needs Asynchronous processing and a guaranteed level of reliability and security. Rest doesn’t have a standard messaging system and expects clients to deal with communication failures by retrying.
If the security is a major concern and the resources are not limited then we should use SOAP web services. Like if we are creating a web service for payment gateways, financial and telecommunication related work then we should go with SOAP as here high security is needed.
source1
source2
IMHO you can't compare SOAP and REST where those are two different things.
SOAP is a protocol and REST is a software architectural pattern. There is a lot of misconception in the internet for SOAP vs REST.
SOAP defines XML based message format that web service-enabled applications use to communicate each other over the internet. In order to do that the applications need prior knowledge of the message contract, datatypes, etc..
REST represents the state(as resources) of a server from an URL.It is stateless and clients should not have prior knowledge to interact with server beyond the understanding of hypermedia.
First of all: officially, the correct question would be web services + WSDL + SOAP vs REST.
Because, although the web service, is used in the loose sense, when using the HTTP protocol to transfer data instead of web pages, officially it is a very specific form of that idea. According to the definition, REST is not "web service".
In practice however, everyone ignores that, so let's ignore it too
There are already technical answers, so I'll try to provide some intuition.
Let's say you want to call a function in a remote computer, implemented in some other programming language (this is often called remote procedure call/RPC). Assume that function can be found at a specific URL, provided by the person who wrote it. You have to (somehow) send it a message, and get some response. So, there are two main questions to consider.
what is the format of the message you should send
how should the message be carried back and forth
For the first question, the official definition is WSDL. This is an XML file which describes, in detailed and strict format, what are the parameters, what are their types, names, default values, the name of the function to be called, etc. An example WSDL here shows that the file is human-readable (but not easily).
For the second question, there are various answers. However, the only one used in practice is SOAP. Its main idea is: wrap the previous XML (the actual message) into yet another XML (containing encoding info and other helpful stuff), and send it over HTTP. The POST method of the HTTP is used to send the message, since there is always a body.
The main idea of this whole approach is that you map a URL to a function, that is, to an action. So, if you have a list of customers in some server, and you want to view/update/delete one, you must have 3 URLS:
myapp/read-customer and in the body of the message, pass the id of the customer to be read.
myapp/update-customer and in the body, pass the id of the customer, as well as the new data
myapp/delete-customer and the id in the body
The REST approach sees things differently. A URL should not represent an action, but a thing (called resource in the REST lingo). Since the HTTP protocol (which we are already using) supports verbs, use those verbs to specify what actions to perform on the thing.
So, with the REST approach, customer number 12 would be found on URL myapp/customers/12. To view the customer data, you hit the URL with a GET request. To delete it, the same URL, with a DELETE verb. To update it, again, the same URL with a POST verb, and the new content in the request body.
For more details about the requirements that a service has to fulfil to be considered truly RESTful, see the Richardson maturity model. The article gives examples, and, more importantly, explains why a (so-called) SOAP service, is a level-0 REST service (although, level-0 means low compliance to this model, it's not offensive, and it is still useful in many cases).
Among many others already covered in the many answers, I would highlight that SOAP enables to define a contract, the WSDL, which define the operations supported, complex types, etc.
SOAP is oriented to operations, but REST is oriented at resources.
Personally I would select SOAP for complex interfaces between internal enterprise applications, and REST for public, simpler, stateless interfaces with the outside world.
Addition for:
++ A mistake that’s often made when approaching REST is to think of it as “web services with URLs”—to think of REST as another remote procedure call (RPC) mechanism, like SOAP, but invoked through plain HTTP URLs and without SOAP’s hefty XML namespaces.
++ On the contrary, REST has little to do with RPC. Whereas RPC is service oriented and focused on actions and verbs, REST is resource oriented, emphasizing the things and nouns that comprise an application.
A lot of these answers entirely forgot to mention hypermedia controls (HATEOAS) which is completely fundamental to REST. A few others touched on it, but didn't really explain it so well.
This article should explain the difference between the concepts, without getting into the weeds on specific SOAP features.
REST API
RESTful APIs are the most famous type of API. REST stands REpresentational State Transfer.
REST APIs are APIs that follow standardized principles, properties, and constraints.
You can access resources in the REST API using HTTP verbs.
REST APIs operate on a simple request/response system. You can send a request using these HTTP methods:
GET
POST
PUT
PATCH
DELETE
TRACE
OPTIONS
CONNECT
HEAD
Here are the most common HTTP verbs
GET (read existing data)
POST (create a new response or data)
PATCH (update the data)
DELETE (delete the data)
The client can make requests using HTTP verbs followed by the endpoint.
The endpoint (or route) is the URL you request for. The path determines the resource you’re requesting.
When you send a request to an endpoint, it responds with the relevant data, generally formatted as JSON, XML, plain text, images, HTML, and more.
REST APIs can also be designed with many different endpoints that return different types of data. Accessing multiple endpoints with a REST API requires various API calls.
An actual RESTful API follows the following five constraints:
Client-Server Architecture
The client requests the data from the server with no third-party interpretation.
Statelessness
Statelessness means that every HTTP request happens in complete isolation. Each request contains the information necessary to service the request. The server never relies on information from previous requests. There’s no state.
Cacheability
Responses can be explicitly or implicitly defined as cacheable or non-cacheable to improve scalability and performance. For example, enabling the cache of GET requests can improve the response times of requests for resource data.
Layering
Different layers of the API architecture should work together, creating a scalable system that is easy to update or adjust.
Uniform Interface
Communication between the client and the server must be done in a standardized language that is independent of both. This improves scalability and flexibility.
REST APIs are a good fit for projects that need to be
Flexible
Scalable
Fast
SOAP API
SOAP is a necessary protocol that helped introduce the widespread use of APIs.
SOAP is the acronym for Simple Object Access Protocol.
SOAP is a standardized protocol that relies on XML to make requests and receive responses.
Even though SOAP is based on XML, the SOAP protocol is still in wide usage.
SOAP APIs make data available as a service and are typically used when performing transactions involving multiple API calls or applications where security is the primary consideration.
SOAP was initially developed for Microsoft in 1998 to provide a standard mechanism for integrating services on the internet regardless of the operating system, object model, or programming language.
The “S” in SOAP stands for Simple, and for a good reason — SOAP can be used with less complexity as it requires less coding in the app layer for transactions, security, and other functions.
SOAP has three primary characteristics:
Extensibility of SOAP API
SOAP allows for extensions that introduce more robust features, such as Windows Server Security, Addressing, and more.
Neutrality of SOAP API
SOAP is capable of operating over a wide range of protocols, like UDP, JMS, SMTP, TCP, and HTTP.can operate.
Independence of SOAP API
SOAP API responses are purely based on XML. Therefore SOAP APIs are platform and language independent.
Developers continue to debate the pros and cons of using SOAP and REST. The best one for your project will be the one that aligns with your needs.
SOAP APIs remain a top choice for corporate entities and government organizations that prioritize security, even though REST has largely dominated web applications.
SOAP is more secure than REST as it uses WS-Security for transmission along with Secure Socket Layer
SOAP also has more excellent transactional reliability, which is another reason why SOAP historically has been favored by the banking industry and other large entities.
What is REST
REST stands for representational state transfer, it's actually an architectural style for creating Web API which treats everything(data or functionality) as recourse.
It expects; exposing resources through URI and responding in multiple formats and representational transfer of state of the resources in stateless manner. Here I am talking about two things:
Stateless manner: Provided by HTTP.
Representational transfer of state: For example if we are adding an employee. .
into our system, it's in POST state of HTTP, after this it would be in GET state of HTTP, PUT and DELETE likewise.
REST can use SOAP web services because it is a concept and can use any protocol like HTTP, SOAP.SOAP uses services interfaces to expose the business logic. REST uses URI to expose business logic.
REST is not REST without HATEOAS. This means that a client only knows the entry point URI and the resources are supposed to return links the client should follow. Those fancy documentation generators that give URI patterns for everything you can do in a REST API miss the point completely. They are not only documenting something that's supposed to be following the standard, but when you do that, you're coupling the client to one particular moment in the evolution of the API, and any changes on the API have to be documented and applied, or it will break.
HATEOAS, an abbreviation for Hypermedia As The Engine Of Application State, is a constraint of the REST application architecture that distinguishes it from most other network application architectures. The principle is that a client interacts with a network application entirely through hypermedia provided dynamically by application servers. A REST client needs no prior knowledge about how to interact with any particular application or server beyond a generic understanding of hypermedia. By contrast, in some service-oriented architectures (SOA), clients and servers interact through a fixed interface shared through documentation or an interface description language (IDL).
Reference 1
Reference 2
Although SOAP and REST share similarities over the HTTP protocol, SOAP is a more rigid set of messaging patterns than REST. The rules in SOAP are relevant because we can’t achieve any degree of standardization without them. REST needs no processing as an architecture style and is inherently more versatile. In the spirit of information exchange, both SOAP and REST depend on well-established laws that everybody has decided to abide by.
The choice of SOAP vs. REST is dependent on the programming language you are using the environment you are using and the specifications.
To answer this question it’s useful to understand the evolution of the architecture of distributed applications from simple layered architectures, to object & service based, to resources based, & nowadays we even have event based architectures. Most large systems use a combination of styles.
The first distributed applications had layered architectures. I'll assume everyone here knows what layers are. These structures are neatly organized, and can be stacks or cyclical structures. Effort is made to maintain a unidirectional data flow.
Object-based architectures evolved out of layered architectures and follow a much looser model. Here, each component is an object (often called a distributed object). The objects interact with one another using a mechanism similar to remote procedure calls - when a client binds to a distributed object it loads an implementation of the objects interface into its address space. The RPC stub can marshal a request & receive a response. Likewise the objects interface on the server is an RPC style stub. The structure of these object based systems is not as neatly organized, it looks more like an object graph.
The interface of a distributed object conceals its implementation. As with layered components, if the interface is clearly defined the internal implementation can be altered - even replaced entirely.
Object-based architectures provide the basis for encapsulating services. A service is provided by a self-contained entity, though internally it can make use of other services. Gradually object-based architectures evolved into service-oriented architectures (SOAs).
With SOA, a distributed application is composed of services. These services can be provided across administrative domains - they may be available across the web (i.e. a storage service offered by a cloud provider).
As web services became popular, and more applications started using them, service composition (combining services to form new ones) became more important. One of the problems with SOA was that integrating different services could become extremely complicated.
While SOAP is a protocol, its use implies a service oriented architecture. SOAP attempted to provide a standard for services whereby they would be composable and easily integrated.
Resource-based architectures were a different approach to solving the integration problems of SOA. The idea is to treat the distributed system as a giant collection of resources that are individually managed by components.
This led to the development of RESTful architectures. One thing that characterizes RESTful services is stateless execution. This is different than SOA where the server maintains the state.
So… how do service-specific interfaces, as provided by service-oriented architectures (including those that use SOAP) compare with resource-based architecture like REST?
While REST is simple, it does not provide a simple interface for complex communication schemes. For example, if you are required to use transactions REST is not appropriate, it is better to keep the complex state encapsulated on the server than have the client manage the transaction. But there are many scenarios where the orthogonal use of resources in RESTful architectures greatly simplifies integration of services in what would otherwise mean an explosion of service interfaces. Another tradeoff is resource-based architectures put more complexity on the client & increase traffic over the network while service-based increase the complexity of the server & tax its memory & CPU resources.
Some people have also mentioned common HTTP services or other services that do not satisfy the requirements of RESTful architecture or SOAP. These too can be categorized as either service-based or resource-based. These have the advantage of being simpler to implement. You'd only use such an approach if you knew your service will never need to be integrated across administrative domains since this makes no attempt at fixing the integration issues that arise.
These sorts of HTTP-based services, especially Pseudo-RESTful services are still the most common types. Implementing SOAP is complicated and should only be used if you really need it - i.e. you need a service that's easily integrated across domains and you want it to have a service-interface. There are still cases where this is needed. A true RESTful service is also difficult to implement, though not as difficult as SOAP.
I have heard a lot of people talking recently about middleware, but what is the exact definition of middleware? When I look into middleware, I find a lot of information and some definitions, but while reading these information and definitions, it seems that mostly all 'wares' are in the middle of something. So, are all things middleware?
Or do you have an example of a ware that isn't middleware?
Lets say your company makes 4 different products, your client has another 3 different products from another 3 different companies.
Someday the client thought, why don't we integrate all our systems into one huge system. Ten minutes later their IT department said that will take 2 years.
You (the wise developer) said, why don't we just integrate all the different systems and make them work together? The client manager staring at you... You continued, we will use a Middleware, we will study the Inputs/Outputs of all different systems, the resources they use and then choose an appropriate Middleware framework.
Still explaining to the non tech manager
With Middleware framework in the middle, the first system will produce X stuff, the system Y and Z would consume those outputs and so on.
Middleware is a terribly nebulous term. What is "middleware" in one case won't be in another. In general, you can expect something classed as middleware to have the following characteristics:
Primarily (usually exclusively) software; usually doesn't need any specialized hardware.
If it weren't there, applications that depend on it would have to incorporate it as part of their application and would experience a lot of duplication.
Almost certainly connects two applications and passes data between them.
You'll notice that this is pretty much the same definition as an operating system. So, for instance, a TCP/IP stack or caching could be considered middleware. But your OS could provide the same features, too. Indeed, middleware can be thought of like a special extension to an operating system, specific to a set of applications that depend on it. It just provides a higher-level service.
Some examples of middleware:
distributed cache
message queue
transaction monitor
packet rewriter
automated backup system
Wikipedia has a quite good explanation: http://en.wikipedia.org/wiki/Middleware
It starts with
Middleware is computer software that connects software components or applications. The software consists of a set of services that allows multiple processes running on one or more machines to interact.
What is Middleware gives a few examples.
There are (at least) three different definitions I'm aware of
in business computing, middleware is messaging and integration software between applications and services
in gaming, middleware is pretty well anything that is provided by a third-party
in (some) embedded software systems, middleware provides services that applications use, which are composed out of the functions provided by the hardware abstraction layer - it sits between the application layer and the hardware abstraction layer.
Simply put Middleware is a software component which provides services to integrate disparate systems together.
In an complex enterprise environment, there are a number of challenges when you need to integrate two or more enterprise systems together to talk to each other. Normally these systems do not understand each others language as they are developed on different platforms using different languages (like C++, Java, Cobol, etc.).
So here comes middleware software in picture which provides services like
transformation of messages formats from one app to other,
routing and enriching messages besides taking care of security,
encryption,
validation and
applying different business rules to these messages.
A typical example of middleware is an ESB products like IBM message broker (WMB/IIB), WESB, Datapower XI50, Oracle Fusion, Mule and many others.
Therefore, middleware sits mostly in between the service consuming apps and services provider apps and help these apps to talk to each other.
Middleware is about how our application responds to incoming requests. Middlewares look into the incoming request, and make decisions based on this request. We can build entire applications only using middlewares. For e.g. ASP.NET is a web framework comprising of following chief HTTP middleware components.
Exception/error handling
Static file server
Authentication
MVC
As shown in the above diagram, there are various middleware components in ASP.NET which receive the incoming request, and redirect it to a C# class (in this case a controller class).
Middleware is a general term for software that serves to "glue together" separate, often complex and already existing, programs. Some software components that are frequently connected with middleware include enterprise applications and Web services.
There is a common definition in web application development which is (and I'm making this wording up but it seems to fit): A component which is designed to modify an HTTP request and/or response but does not (usually) serve the response in its entirety, designed to be chained together to form a pipeline of behavioral changes during request processing.
Examples of tasks that are commonly implemented by middleware:
Gzip response compression
HTTP authentication
Request logging
The key point here is that none of these is fully responsible for responding to the client. Instead each changes the behavior in some way as part of the pipeline, leaving the actual response to come from something later in the sequence (pipeline).
Usually, the middlewares are run before some sort of "router", which examines the request (often the path) and calls the appropriate code to generate the response.
Personally, I hate the term "middleware" for its genericity but it is in common use.
Here is an additional explanation specifically applicable to Ruby on Rails.
Middleware stands between web applications and web services that natively can't communicate and often are written in different languages/frameworks.
One such example is OWIN middleware for .NET environment, before owin people were forced to host web apps in a microsoft hosting software called IIS. After owin was developed, it has added capacity to host both in IIS and self host, in IIS was just added support for Owin which acted as an interface. Also it become possible to host .NET web apps on Linux via Mono, which again added support for Owin.
It also added capacity to create Single Page Applications, Owin handling Http request/response context, so on top of owin you can add authentication/authorization logic via OAuth2 for example, you can configure middleware to register a class which contains logic of user authentification (for ex. OAuth2 implementation) or class which contains logic of how to manage http request/response messages, that way you can make one application communicate with other applications/services via different data format (like json, xml, etc if you are targeting web).
Some examples of middleware: CORBA, Remote Method Invocation (RMI),...
The examples mentioned above are all pieces of software allowing you to take care of communication between different processes (either running on the same machine or distributed over e.g. the internet).
From my own experience with webwork, a middleware was stuff between users (the web browser) and the backend database. It was the software that took stuff that users put in (example: orders for iPads, did some magical business logic, i.e. check if there are enough iPads available to fill the order) and updated the backend database to reflect those changes.
It is just a piece of software or a tool on which your application executes and rapplication capabilities with respect to high availability,scalability,integrating with other softwares or systems without you bothering about your application level code changes .
For example : The operating system on which your application runs requires an I.P change , you do not have to worry about it in your code , it is the middleware stack on which you can simple update the configuration.
Example 2 : You experience problems with your runtime memory allocation and feel that the your application usage has increased , you do not have to much about it unless you have a bug or bottleneck in your code , it is easily achievable by tuning middleware software configuration on which your application runs.
Example 3 : You have multiple disparate software and you need them to talk to each other or send data in a common format which is understandable by all the systems then this is where middleware systems comes handy.
Hope the information provided helps.
it is a software layer between the operating system
and applications on each side of a distributed computing system in a network. In fact it connects heterogeneous network and software systems.
If I am not wrong, in software application framework, based on the context, you can consider middleware for the following roles that can be combined in order to perform certain activities in between the user request and the application response.
Adapter
Sanitizer
Validator
I always thought of it as the oldest software I have had to install. The total app used a web server, a database server, and an application server. The web server being the middleware between the data and the app.