What exactly is RESTful programming?
REST is the underlying architectural principle of the web. The amazing thing about the web is the fact that clients (browsers) and servers can interact in complex ways without the client knowing anything beforehand about the server and the resources it hosts. The key constraint is that the server and client must both agree on the media used, which in the case of the web is HTML.
An API that adheres to the principles of REST does not require the client to know anything about the structure of the API. Rather, the server needs to provide whatever information the client needs to interact with the service. An HTML form is an example of this: The server specifies the location of the resource, and the required fields. The browser doesn't know in advance where to submit the information, and it doesn't know in advance what information to submit. Both forms of information are entirely supplied by the server. (This principle is called HATEOAS.)
So, how does this apply to HTTP, and how can it be implemented in practice? HTTP is oriented around verbs and resources. The two verbs in mainstream usage are GET and POST, which I think everyone will recognize. However, the HTTP standard defines several others such as PUT and DELETE. These verbs are then applied to resources, according to the instructions provided by the server.
For example, Let's imagine that we have a user database that is managed by a web service. Our service uses a custom hypermedia based on JSON, for which we assign the mimetype application/json+userdb (There might also be an application/xml+userdb and application/whatever+userdb - many media types may be supported). The client and the server has both been programmed to understand this format, but they don't know anything about each other. As Roy Fielding points out:
A request for the base resource
We know from the description of our media that we can find information about related resources from sections called "links". This is called Hypermedia controls. In this case, we can tell from such a section that we can find a user list by making another request for
We can tell a lot from this response. For instance, we now know we can create a new user by POSTing to
We also know that we can change existing data:
Notice that we are using different HTTP verbs (GET, PUT, POST, DELETE etc.) to manipulate these resources, and that the only knowledge we presume on the clients part is our media definition.
(This answer has been subject of a fair amount of criticism for missing the point. For the most part, that has been a fair critique. What I originally described was more in line with how REST was usually implemented a few years ago when I first wrote this, rather than its true meaning. I've revised the answer to better represent the real meaning.)
IMHO (and I tend to be in the minority), RESTful programming is about:
The last one is probably the most important in terms of consequences and overall effectiveness of REST. Overall, most of the RESTful discussions seem to center on HTTP and its usage from a browser and what not. I understand that R. Fielding coined the term when he described the architecture and decisions that lead to HTTP. His thesis is more about the architecture and cache-ability of resources than it is about HTTP.
If you are really interested in what a RESTful architecture is and why it works, read his thesis a few times and read the whole thing not just Chapter 5! Next look into why DNS works. Read about the hierarchical organization of DNS and how referrals work. Then read and consider how DNS caching works. Finally, read the HTTP specifications (RFC2616 and RFC3040 in particular) and consider how and why the caching works the way that it does. Eventually, it will just click. The final revelation for me was when I saw the similarity between DNS and HTTP. After this, understanding why SOA and Message Passing Interfaces are scalable starts to click.
I think that the most important trick to understanding the architectural importance and performance implications of a RESTful and Shared Nothing architectures is to avoid getting hung up on the technology and implementation details. Concentrate on who owns resources, who is responsible for creating/maintaining them, etc. Then think about the representations, protocols, and technologies.
This is what it might look like:
The server responds:
In the future, you can then retrieve the user information:
The server responds:
A great book on REST is REST in Practice.
See Martin Fowlers article the Richardson Maturity Model (RMM) for an explanation on what an RESTful service is.
To be RESTful a Service needs to fulfill the Hypermedia as the Engine of Application State. (HATEOAS), that is, it needs to reach level 3 in the RMM, read the article for details or the slides from the qcon talk.
REST Litmus Test for Web Frameworks is a similar maturity test for web frameworks.
Approaching pure REST: Learning to love HATEOAS is a good collection of links.
REST versus SOAP for the Public Cloud discusses the current levels of REST usage.
REST and versioning discusses Extensibility, Versioning, Evolvability, etc. through Modifiability
One of the best reference I found when I try to find the simple real meaning of rest.
It's programming where the architecture of your system fits the REST style laid out by Roy Fielding in his thesis. Since this is the architectural style that describes the web (more or less), lots of people are interested in it.
Bonus answer: No. Unless you're studying software architecture as an academic or designing web services, there's really no reason to have heard the term.
REST is using the various HTTP methods (mainly GET/PUT/DELETE) to manipulate data.
Rather than using a specific URL to delete a method (say,
For example, instead a set of URLs which might look like some of the following..
You use the HTTP "verbs" and have..
I apologize if I'm not answering the question directly (I'm new to SO and don't have pts to comment), but it's easier to understand all this with more detailed examples. Fielding is not easy to understand due to all the abstraction and terminology.
There's a fairly good example here:
And even better, there's a clean explanation with simple examples here (the powerpoint is more comprehensive, but you can get most of it in the html version):
After reading the examples, I could see why Ken is saying that REST is hypertext-driven. I'm not actually sure that he's right though, because that /user/123 is a URI that points to a resource, and it's not clear to me that it's unRESTful just because the client knows about it "out-of-band."
That xfront document explains the difference between REST and SOAP, and this is really helpful too. When Fielding says, "That is RPC. It screams RPC.", it's clear that RPC is not RESTful, so it's useful to see the exact reasons for this. (SOAP is a type of RPC.)
An architectural style called REST (Representational State Transfer) advocates that
REST proponents tend to favor
but the REST architecture does not require these “pretty URLs”. A GET request with a parameter
is every bit as RESTful.
Keep in mind that GET requests should never be used for updating information. For example, a GET request for adding an item to a cart
would not be appropriate. GET requests should be idempotent. That is, issuing a request twice should be no different from issuing it once. That’s what makes the requests cacheable. An “add to cart” request is not idempotent—issuing it twice adds two copies of the item to the cart. A POST request is clearly appropriate in this context. Thus, even a RESTful web application needs its share of POST requests.
This is taken from the excellent book
Restful programming is coding on the weekend on the couch.
For More reference : what exactly is restful programming ?
I see a bunch of answers that say putting everything about user 123 at resource "/user/123" is RESTful.
Roy Fielding, who coined the term, says REST APIs must be hypertext-driven. In particular, "A REST API must not define fixed resource names or hierarchies".
So if your "/user/123" path is hardcoded on the client, it's not really RESTful. A good use of HTTP, maybe, maybe not. But not RESTful. It has to come from hypertext.
What is REST?
REST in official words, REST is an architectural style built on certain principles using the current “Web” fundamentals. There are 5 basic fundamentals of web which are leveraged to create REST services.
I would say RESTful programming would be about creating systems (API) that follow the REST architectural style.
I found this fantastic, short, and easy to understand tutorial about REST by Dr. M. Elkstein and quoting the essential part that would answer your question for the most part:
I don't think you should feel stupid for not hearing about REST outside Stack Overflow..., I would be in the same situation!; answers to this other SO question on Why is REST getting big now could could ease some feelings.
The answer is very simple, there is a dissertation written by Roy Fielding.]1 In that dissertation he defines the REST principles. If an application fulfills all of those principles, then that is a REST application.
The term RESTful was created because ppl exhausted the word REST by calling their non-REST application as REST. After that the term RESTful was exhausted as well. Nowadays we are talking about Web APIs and Hypermedia APIs, because the most of the so called REST applications did not fulfill the HATEOAS part of the uniform interface constraint.
The REST constraints are the following:
REST constraints result a highly scalable system in where the clients are decoupled from the implementations of the services. So the clients can be reusable, general just like the browsers on the web. The clients and the services share the same standards and vocabs, so they can understand each other despite the fact that the client does not know the implementation details of the service. This makes possible to create automated clients which can find and utilize REST services to achieve their goals. In long term these clients can communicate to each other and trust each other with tasks, just like humans do. If we add learning patterns to such clients, then the result will be one or more AI using the web of machines instead of a single server park. So at the end the dream of Berners Lee: the semantic web and the artificial intelligence will be reality. So in 2030 we end up terminated by the Skynet. Until then ... ;-)
If I had to reduce the original dissertation on REST to just 3 short sentences, I think the following captures its essence:
After that, it's easy to fall into debates about adaptations, coding conventions, and best practices.
Interestingly, there is no mention of HTTP POST, GET, DELETE, or PUT operations in the dissertation. That must be someone's later interpretation of a "best practice" for a "uniform interface".
When it comes to web services, it seems that we need some way of distinguishing WSDL and SOAP based architectures which add considerable overhead and arguably much unnecessary complexity to the interface. They also require additional frameworks and developer tools in order to implement. I'm not sure if REST is the best term to distinguish between common-sense interfaces and overly engineered interfaces such as WSDL and SOAP. But we need something.
In other words you're writing simple point-to-point network applications over HTTP which uses verbs such as GET, POST, PUT or DELETE by implementing RESTful architecture which proposes standardization of the interface each “resource” exposes. It is nothing that using current features of the web in a simple and effective way (highly successful, proven and distributed architecture). It is an alternative to more complex mechanisms like SOAP, CORBA and RPC.
RESTful programming conforms to Web architecture design and, if properly implemented, it allows you to take the full advantage of scalable Web infrastructure.
REST is an architectural pattern and style of writing distributed applications. It is not a programming style in the narrow sense.
Saying you use the REST style is similar to saying that you built a house in a particular style: for example Tudor or Victorian. Both REST as an software style and Tudor or Victorian as a home style can be defined by the qualities and constraints that make them up. For example REST must have Client Server separation where messages are self-describing. Tudor style homes have Overlapping gables and Roofs that are steeply pitched with front facing gables. You can read Roy's dissertation to learn more about the constraints and qualities that make up REST.
REST unlike home styles has had a tough time being consistently and practically applied. This may have been intentional. Leaving its actual implementation up to the designer. So you are free to do what you want so as long as you meet the constraints set out in the dissertation you are creating REST Systems.
The entire web is based on REST (or REST was based on the web). Therefore as a web developer you might want aware of that although it's not necessary to write good web apps.
Representational State Transfer (REST) is a software architecture style consisting of guidelines and best practices for creating scalable web services.REST is a coordinated set of constraints applied to the design of components in a distributed hypermedia system that can lead to a more performant and maintainable architecture.
REST has gained widespread acceptance across the Web as a simpler alternative to SOAP and WSDL-based Web services. RESTful systems typically, but not always, communicate over the Hypertext Transfer Protocol with the same HTTP verbs (GET, POST, PUT, DELETE, etc.) used by web browsers to retrieve web pages and send data to remote servers.
The REST architectural style was developed by W3C Technical Architecture Group (TAG) in parallel with HTTP 1.1, based on the existing design of HTTP 1.0. The World Wide Web represents the largest implementation of a system conforming to the REST architectural style.
The architectural properties of REST are realized by applying specific interaction constraints to components, connectors, and data elements. The formal REST constraints are:
A uniform interface separates clients from servers. This separation of concerns means that, for example, clients are not concerned with data storage, which remains internal to each server, so that the portability of client code is improved. Servers are not concerned with the user interface or user state, so that servers can be simpler and more scalable. Servers and clients may also be replaced and developed independently, as long as the interface between them is not altered.
The client–server communication is further constrained by no client context being stored on the server between requests. Each request from any client contains all the information necessary to service the request, and session state is held in the client. The session state can be transferred by the server to another service such as a database to maintain a persistent state for a period and allow authentication. The client begins sending requests when it is ready to make the transition to a new state. While one or more requests are outstanding, the client is considered to be in transition. The representation of each application state contains links that may be used the next time the client chooses to initiate a new state-transition.
As on the World Wide Web, clients can cache responses. Responses must therefore, implicitly or explicitly, define themselves as cacheable, or not, to prevent clients from reusing stale or inappropriate data in response to further requests. Well-managed caching partially or completely eliminates some client–server interactions, further improving scalability and performance.
A client cannot ordinarily tell whether it is connected directly to the end server, or to an intermediary along the way. Intermediary servers may improve system scalability by enabling load balancing and by providing shared caches. They may also enforce security policies.
Code on demand (optional)
The uniform interface constraint is fundamental to the design of any REST service.The uniform interface simplifies and decouples the architecture, which enables each part to evolve independently.
I think the point of restful is the separation of the statefulness into a higher layer while making use of the internet (protocol) as a stateless transport layer. Most other approaches mix things up.
It's been the best practical approach to handle the fundamental changes of programming in internet era. Regarding the fundamental changes, Erik Meijer has a discussion on show here: http://www.infoq.com/interviews/erik-meijer-programming-language-design-effects-purity#view_93197 . He summarizes it as the five effects, and presents a solution by designing the solution into a programming language. The solution, could also be achieved in the platform or system level, regardless of the language. The restful could be seen as one of the solutions that has been very successful in the current practice.
With restful style, you get and manipulate the state of the application across an unreliable internet. If it fails the current operation to get the correct and current state, it needs the zero-validation principal to help the application to continue. If it fails to manipulate the state, it usually uses multiple stages of confirmation to keep things correct. In this sense, rest is not itself a whole solution, it needs the functions in other part of the web application stack to support its working.
Given this view point, the rest style is not really tied to internet or web application. It's a fundamental solution to many of the programming situations. It is not simple either, it just makes the interface really simple, and copes with other technologies amazingly well.
Just my 2c.
Edit: Two more important aspects:
Quote from another post: "
The point of rest is that if we agree to use a common language for basic operations (the http verbs), the infrastructure can be configured to understand them and optimize them properly, for example, by making use of caching headers to implement caching at all levels.
With a properly implemented restful GET operation, it shouldn't matter if the information comes from your server's DB, your server's memcache, a CDN, a proxy's cache, your browser's cache or your browser's local storage. The fasted, most readily available up to date source can be used.
Saying that Rest is just a syntactic change from using GET requests with an action parameter to using the available http verbs makes it look like it has no benefits and is purely cosmetic. The point is to use a language that can be understood and optimized by every part of the chain. If your GET operation has an action with side effects, you have to skip all HTTP caching or you'll end up with inconsistent results.
I love Wiki answer, though wiki has been my best Guide in learning. I wonder no one is referencing wiki, well nevertheless here is awesome explanation about RESTFUL programming:
In computing, representational state transfer (REST) is an architectural style consisting of a coordinated set of components, connectors, and data elements within a distributed hypermedia system, where the focus is on component roles and a specific set of interactions between data elements rather than implementation details. Its purpose is to induce performance, scalability, simplicity, modifiability, visibility, portability, and reliability. REST is the software architectural style of the World Wide Web.
The term representational state transfer was introduced and defined in 2000 by Roy Fielding in his doctoral dissertation at UC Irvine. REST has been applied to describe desired web architecture, to identify existing problems, to compare alternative solutions and to ensure that protocol extensions would not violate the core constraints that make the web successful. Fielding used REST to design HTTP 1.1 and Uniform Resource Identifiers (URI).
To the extent that systems conform to the constraints of REST they can be called RESTful. RESTful systems typically, but not always, communicate over Hypertext Transfer Protocol (HTTP) with the same HTTP verbs (GET, POST, PUT, DELETE, etc.) that web browsers use to retrieve web pages and to send data to remote servers. REST systems interface with external systems as web resources identified by Uniform Resource Identifiers (URIs), for example /people/tom, which can be operated upon using standard verbs such as GET /people/tom.
The name "Representational State" is intended to evoke an image of how a well-designed Web application behaves: a network of web pages (a virtual state-machine), where the user progresses through the application by selecting links (state transitions), resulting in the next page (representing the next state of the application) being transferred to the user and rendered for their use.
REST was defined by Roy Thomas Fielding in his 2000 PhD dissertation "Architectural Styles and the Design of Network-based Software Architectures".1 Fielding developed the REST architectural style in parallel with HTTP 1.1 of 1996-1999, based on the existing design of HTTP 1.0 of 1996.
In a retrospective look at the development of REST Roy Fielding said:
The architectural properties affected by the constraints of the REST architectural style are
The architectural properties of REST are realized by applying specific interaction constraints to components, connectors, and data elements. One can characterise applications conforming to the REST constraints described in this section as "RESTful". If a service violates any of the required constraints, it cannot be considered RESTful. Complying with these constraints, and thus conforming to the REST architectural style, enables any kind of distributed hypermedia system to have desirable non-functional properties, such as performance, scalability, simplicity, modifiability, visibility, portability, and reliability.
The formal REST constraints are Client–server See also: Client–server model
A uniform interface separates clients from servers. This separation of concerns means that, for example, clients are not concerned with data storage, which remains internal to each server, so that the portability of client code is improved. Servers are not concerned with the user interface or user state, so that servers can be simpler and more scalable. Servers and clients may also be replaced and developed independently, as long as the interface between them is not altered. Stateless See also: Stateless protocol
The client–server communication is further constrained by no client context being stored on the server between requests. Each request from any client contains all the information necessary to service the request, and session state is held in the client. The session state can be transferred by the server to another service such as a database to maintain a persistent state for a period and allow authentication. The client begins sending requests when it is ready to make the transition to a new state. While one or more requests are outstanding, the client is considered to be in transition. The representation of each application state contains links that may be used the next time the client chooses to initiate a new state-transition. Cacheable See also: Web cache
As on the World Wide Web, clients and intermediaries can cache responses. Responses must therefore, implicitly or explicitly, define themselves as cacheable, or not, to prevent clients from reusing stale or inappropriate data in response to further requests. Well-managed caching partially or completely eliminates some client–server interactions, further improving scalability and performance. Layered system See also: Layered system
A client cannot ordinarily tell whether it is connected directly to the end server, or to an intermediary along the way. Intermediary servers may improve system scalability by enabling load balancing and by providing shared caches. They may also enforce security policies. Code on demand (optional) See also: Client-side scripting
The uniform interface constraint is fundamental to the design of any REST service.1 The uniform interface simplifies and decouples the architecture, which enables each part to evolve independently. The four constraints for this uniform interface are
Identification of resources
Manipulation of resources through these representations When a client holds a representation of a resource, including any metadata attached, it has enough information to modify or delete the resource. Self-descriptive messages Each message includes enough information to describe how to process the message. For example, which parser to invoke may be specified by an Internet media type (previously known as a MIME type).1 Hypermedia as the engine of application state (HATEOAS) Clients make state transitions only through actions that are dynamically identified within hypermedia by the server (e.g., by hyperlinks within hypertext). Except for simple fixed entry points to the application, a client does not assume that any particular action is available for any particular resources beyond those described in representations previously received from the server. There is no universally accepted format for representing links between two resources. RFC 5988 and JSON Hypermedia API Language (proposed) are two popular formats for specifying REST hypermedia links.
Applied to web services
Web service APIs that adhere to the REST architectural constraints are called RESTful APIs. HTTP-based RESTful APIs are defined with the following aspects:
Relationship between URI and HTTP Methods
The following table shows how HTTP methods are typically used in a RESTful API: HTTP methods Uniform Resource Identifier (URI) GET PUT POST DELETE Collection, such as http://api.example.com/resources/ List the URIs and perhaps other details of the collection's members. Replace the entire collection with another collection. Create a new entry in the collection. The new entry's URI is assigned automatically and is usually returned by the operation. Delete the entire collection. Element, such as http://api.example.com/resources/item17 Retrieve a representation of the addressed member of the collection, expressed in an appropriate Internet media type. Replace the addressed member of the collection, or if it does not exist, create it. Not generally used. Treat the addressed member as a collection in its own right and create a new entry in it. Delete the addressed member of the collection.
The PUT and DELETE methods are referred to as idempotent, meaning that the operation will produce the same result no matter how many times it is repeated. The GET method is a safe method (or nullipotent), meaning that calling it produces no side-effects. In other words, retrieving or accessing a record does not change it. The distinction between PUT/DELETE and GET are roughly analogous to the notion of Command-Query Separation (CQS). For example: A query operation (like GET) promises no side-effects (e.g. changes) in data being queried. Commands (like PUT/DELETE) answer no questions about the data, but compute changes applied to the data (e.g. UPDATE or INSERT to use database terms).
Unlike SOAP-based web services, there is no "official" standard for RESTful web APIs. This is because REST is an architectural style, while SOAP is a protocol. Even though REST is not a standard per se, most RESTful implementations make use of standards such as HTTP, URI, JSON, and XML.
The rest resources can be found
** More detail
REST stands for Representational state transfer.
It relies on a stateless, client-server, cacheable communications protocol -- and in virtually all cases, the HTTP protocol is used.
REST is often used in mobile applications, social networking Web sites, mashup tools and automated business processes. The REST style emphasizes that interactions between clients and services is enhanced by having a limited number of operations (verbs). Flexibility is provided by assigning resources (nouns) their own unique universal resource indicators (URIs).
Talking is more than simply exchanging information. A Protocol is actually designed so that no talking has to occur. Each party knows what their particular job is because it is specified in the protocol. Protocols allow for pure information exchange at the expense of having any changes in the possible actions. Talking, on the other hand, allows for one party to ask what further actions can be taken from the other party. They can even ask the same question twice and get two different answers, since the State of the other party may have changed in the interim. Talking is RESTful architecture. Fielding's thesis specifies the architecture that one would have to follow if one wanted to allow machines to talk to one another rather than simply communicate.
REST === HTTP analogy is not correct until you do not stress to the fact that it "MUST" be HATEOAS driven.
Roy himself cleared it here: http://roy.gbiv.com/untangled/2008/rest-apis-must-be-hypertext-driven
A REST API should be entered with no prior knowledge beyond the initial URI (bookmark) and set of standardized media types that are appropriate for the intended audience (i.e., expected to be understood by any client that might use the API). From that point on, all application state transitions must be driven by client selection of server-provided choices that are present in the received representations or implied by the user’s manipulation of those representations. The transitions may be determined (or limited by) the client’s knowledge of media types and resource communication mechanisms, both of which may be improved on-the-fly (e.g., code-on-demand).
[Failure here implies that out-of-band information is driving interaction instead of hypertext.]
REST is a distributed systems (such as WWW) software architecture style, you can imagine that it is a well-designed Web application rules: a group of Internet Web pages (a virtual state machine), in which hyperlink by clicking link (state transition), the result is the next Web page (which means the next state of the application).
REST describes the network system consists of three parts:
REST strictly meet the following conditions:
protected by Shankar Damodaran Jan 15 '14 at 17:55
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