Learning REST in pieces is one thing, while applying all those learned concepts into real application design is completely another challenge. In this tutorial, we will learn to design REST APIs for a network-based application. Please note that the takeaway from this whole exercise is the learning of how to apply REST principles in design process.
Download Ebook Restful Api Design Best Practices In Api Design With Rest Apiuniversity Series Book 3honda motorcycle service manuals online, remington model 11 owners manual free downloads, your cat the owner manual, volvo s80 manual transmission, jensen cd player manual, jon rogawski calculus early transcendentals second edition solutions. REST API’s should be designed for Resources, which can be entities or services, etc., therefore they must always be nouns. For example, instead of /createUser use /users 2.
The very first step in designing a REST API based application is – identifying the objects which will be presented as resources.
For a network-based application, object modeling is pretty much more straightforward. There can be many things such as devices, managed entities, routers, modems, etc. For simplicity sake, we will consider only two resources i.e.
Here configuration is sub-resource of a device. A device can have many configuration options.
Note that both objects/resources in our above model will have a unique identifier, which is the integer id
property.
Now when the object model is ready, it’s time to decide the resource URIs. At this step, while designing the resource URIs – focus on the relationship between resources and its sub-resources. These resource URIs are endpoints for RESTful services.
In our application, a device is a top-level resource. And configuration is sub-resource under the device. Let’s write down the URIs.
Notice that these URIs do not use any verb or operation. It’s crucial not to include any verb in URIs. URIs should all be nouns only.
Now when resource URIs have been decided, let’s work on their representations. Mostly representations are defined in either XML or JSON format. We will see XML examples as its more expressive on how data is composed.
When returning a collection resource, include only the most important information about resources. This will keep the size of payload small, and so will improve the performance of REST APIs.
Opposite to collection URI, here include complete information of a device in this URI. Here, also include a list of links for sub-resources and other supported operations. This will make your REST API HATEOAS driven.
Similar to device collection representation, create configuration collection representation with only minimal information.
Please note that configurations
collection representation inside device
is similar to top-level configurations
URI. Only difference is that configurations
for a device are only two, so only two configuration items are listed as subresource under device.
Now, single configuration resource representation must have all possible information about this resource – including relevant links.
This resource collection of configurations will be a subset of the primary collection of configurations, and will be specific a device only. As it is the subset of primary collection, DO NOT create a different representation data fields than primary collection. Use the same presentation fields as the primary collection.
Notice that this subresource collection has two links. One for its direct representation inside sub-collection i.e. /devices/12345/configurations/333443
and other pointing to its location in primary collection i.e. /configurations/333443
.
Having two links is essential as you can provide access to a device- specific configuration in a more unique manner, and you will have the ability to mask some fields (if design requires it), which shall not be visible in a secondary collection.
This representation should have either exactly similar representation as of Configuration representation from the primary collection, OR you may mask few fields.
This subresource representation will also have an additional link to its primary presentation.
Now, before moving forward to the next section, let’s note down a few observations, so you don’t miss them.
method
represent a POST method. You can have more attributes or form links in altogether new way also.So our resource URIs and their representation are fixed now. Let’s decide the possible operations in the application and map these operations on resource URIs. A user of our network application can perform browse, create, update, or delete operations. So let’s assign them.
If the collection size is large, you can apply paging and filtering as well. e.g., Below requests will fetch the first 20 records from collection.
It will be mostly a small size collection – so no need to enable filtering or soring here.
To get the complete detail of a device or configuration, use GET
operation on singular resource URIs.
Subresource representation will be either same as or a subset of primary presentation.
Create is not idempotent operation, and in HTTP protocol – POST
is also not idempotent. So use POST.
Please note that request payload will not contain any id
attribute, as the server is responsible for deciding it. The response to create request will look like this:
Update operation is an idempotent operation and HTTP PUT
is also is idempotent method. So we can use PUT method for update operations.
PUT response may look like this.
Removing is always a DELETE
operation.
A successful response SHOULD be 202 (Accepted)
if resource has been queues for deletion (async operation), or 200 (OK)
/ 204 (No Content)
if resource has been deleted permanently (sync operation).
In the case of async operation, the application shall return a task id that can be tracked for success/failure status.
Please note that you should put enough analysis in deciding the behavior when a subresource is deleted from the system. Usually, you may want to SOFT DELETE a resource in these requests – in other words, set their status INACTIVE. By following this approach, you will not need to find and remove its references from other places as well.
In a real application, you will need to apply the configuration on the device – OR you may want to remove the configuration from the device (not from the primary collection). You shall use PUT and DELETE methods in this case, because of its idempotent nature.
So far, we have designed only object models, URIs and then decided HTTP methods or operations on them. You need to work on other aspects of the application as well:
1) Logging
2) Security
3) Discovery etc.
In the next article, we will create this application in java to get a more detailed understanding.