By taking a path of Web development, you find yourself in the need of dealing with external APIs (Application Programming Interface) sooner or later. In this article, my goal is to make the most comprehensive list of ways to consume RESTful APIs in your C# projects and show you how to do that on some simple examples. After reading the article you will have more insight into which options are available to you and how to choose the right one next time you need to consume a RESTful API.

What is a RESTful API?

So, before we start, you might be wondering what does API stand for, and what is the RESTful part all about?

To put things simply, APIs are the layers between software applications. You can send the request to the API, and in return, you get the response from it. APIs hide all the nitty-gritty details of the concrete implementation of a software application and expose the interface you should use to communicate with that application.

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The whole internet is the one big spider web made of APIs. We use APIs to communicate and relate information between applications. We have an API for pretty much anything out there. Most of the services you use daily have their own APIs (GoogleMaps, Facebook, Twitter, Instagram, weather portals…)

RESTful part means that API is implemented in accordance with the principles and rules of the REST (Representational State Transfer) which is the underlying architectural principle of the web. RESTful APIs in most cases return the plain text, JSON or XML response. Explaining REST in more detail is out of the scope of this article, but you can read more about REST in our article Top REST API best practices.

How to Consume RESTful APIs

Ok, let’s go to the meaty part of this whole story.

There are several ways to consume a RESTful API in C#:

Every one of these has pros and cons, so let us go through them and see what they offer.

As an example, we will be collecting information about RestSharp repo releases and their publish dates via GitHub API. This information is available publicly and you can see how raw JSON response looks here: RestSharp releases

We are going to utilize the help of the Json.NET library to deserialize the response we get. Also, for some examples, we are going to use the inbuilt deserialization mechanisms of the libraries. It’s up to you to choose which way you prefer because no way is the right way. (You can see the implementation for both mechanisms in the source code).

What I expect to get as a result of the next few examples is a deserialized JArray (for simplicity) that contains RestSharp release information. After that, we can iterate through it to get the following result.

HttpWebRequest/Response Class

It’s the HTTP-specific implementation of WebRequest class which was originally used to deal with HTTP requests, but it was made obsolete and replaced by the WebClient class.

The HttpWebRequest class offers fine-grained control over every aspect of the request making process. As you can imagine, this can be the double-edged sword and you can easily end up losing enormous amounts of time fine-tuning your requests. On the other hand, this might just be what you need for your specific case.

HttpWebRequest class does not block the user interface, which is, I am sure you will agree with this one, pretty important.

HttpWebResponse class provides a container for the incoming responses.

This is a simple example of how to consume an API using these classes.



public class HttpWebRequestHandler : IRequestHandler { public string GetReleases(string url) { var request = (HttpWebRequest)WebRequest.Create(url); request.Method = "GET"; request.UserAgent = RequestConstants.UserAgentValue; request.AutomaticDecompression = DecompressionMethods.Deflate | DecompressionMethods.GZip; var content = string.Empty; using (var response = (HttpWebResponse)request.GetResponse()) { using (var stream = response.GetResponseStream()) { using (var sr = new StreamReader(stream)) { content = sr.ReadToEnd(); } } } return content; } }

Although a simple example, it becomes much more complicated when you need to deal with more sophisticated scenarios like posting form information, authorizing etc.

WebClient Class

This class is a wrapper around HttpWebRequest . It simplifies the process by abstracting the details of the HttpWebRequest from the developer. The code is easier to write and you are less likely to make mistakes this way. If you want to write less code, not worry about all the details, and the execution speed is a non-factor, consider using WebClient class.

This example should give you the rough idea of how much easier is to use WebClient compared to the HttpWebRequest / HttpWebResponse approach.



public string GetReleases(string url) { var client = new WebClient(); client.Headers.Add(RequestConstants.UserAgent, RequestConstants.UserAgentValue); var response = client.DownloadString(url); return response; }

Much easier, right?

Other then DownloadString method, WebClient class offers a host of other useful methods to make our life easier. We can easily manipulate strings, files or byte arrays using it, and for a price of just a few milliseconds slower than HttpWebRequest / HttpWebResponse approach.

Both the HttpWebRequest / HttpWebResponse and WebClient classes are available in the older versions of .NET. Be sure to check out the MSDN if you are interested what else WebClient has to offer.

HttpClient Class

HttpClient is the “new kid on the block”, and offers some of the modern .NET functionalities that older libraries lack. For example, you can send multiple requests with the single instance of HttpClient , it is not tied to the particular HTTP server or host, makes use of async/await mechanism.

You can find out about the five good reasons to use HttpClient in this video:

Strongly typed headers.

Shared Caches, cook­ies, and credentials

Access to cook­ies and shared cookies

Con­trol over caching and shared cache.

Inject your code mod­ule into the ASP.NET pipeline. Cleaner and mod­u­lar code.

Here is HttpClient in action in our example:



public string GetReleases(string url) { using (var httpClient = new HttpClient()) { httpClient.DefaultRequestHeaders.Add(RequestConstants.UserAgent, RequestConstants.UserAgentValue); var response = httpClient.GetStringAsync(new Uri(url)).Result; return response; } }

HttpClient

For simplicity’s sake, I implemented it synchronously. Everymethod is meant to be used asynchronously and SHOULD be used that way.

Also, I need to mention one more thing. There is a debate whether HttpClient should be wrapped in a using block or statically on the app level. Although it implements IDisposable , it seems that by wrapping it in the using block you can make your app malfunction and get the SocketException. And as Ankit blogs, the performance test results are much in favor of static initialization of the HttpClient . Be sure to read these blog posts as they can help you be more informed about the correct usage of the HttpClient library.

And don’t forget, being modern, HttpClient is exclusive to the .NET 4.5, so you might have trouble using it on some legacy projects.

RestSharp

RestSharp is the OpenSource alternative to standard .NET libraries and one of the coolest .NET libraries out there. It is available as a NuGet package, and there are a few reasons why you should consider trying it out.

Like HttpClient , RestSharp is a modern and comprehensive library, easy and pleasant to use, while still having support for older versions of .NET Framework. It has inbuilt Authentication and Serialization/Deserialization mechanisms but allows you to override them with your custom ones. It is available across platforms and supports OAuth1, OAuth2, Basic, NTLM and Parameter-based Authentication. You can choose to work both synchronously or asynchronously. There is a lot more to this library, and these are just some of the great benefits it offers. For the detailed information on usage and capabilities of RestSharp, you can visit the RestSharp page on GitHub.

Now let’s try to get a list of RestSharp releases using RestSharp 😀



public string GetReleases(string url) { var client = new RestClient(url); var response = client.Execute(new RestRequest()); return response.Content; }

Simple enough. But don’t let that fool you, RestSharp is very flexible and has all the tools you need to achieve almost anything while working with RESTful API.

One thing to note in this example is that I didn’t use RestSharp’s deserialization mechanism due to the example consistency, which is a bit of a waste, but I encourage you to use it as it is really easy and convenient. So you can easily make a container like this:



public class GitHubRelease { [JsonProperty(PropertyName = "name")] public string Name { get; set; } [JsonProperty(PropertyName = "published_at")] public string PublishedAt { get; set; } }

Execute

JsonProperty

List<Release>

public List<GitHubRelease> GetDeserializedReleases(string url) { var client = new RestClient(url); var response = client.Execute<List<GitHubRelease>>(new RestRequest()); return response.Data; }

And after that usemethod to directly deserialize the response to that container. You can add just the properties you need and use attributeto map them to C# properties (nice touch). Since we get the list of releases in our response, we use theas a containing type.A pretty straightforward and elegant way to get our data.

There is a lot more to RestSharp than sending GET requests, so explore and see for yourself how cool it can be.

One final note to add to the RestSharp case is that its repository is in need of maintainers. If you want to learn more about this cool library, I urge you to head over to RestSharp repo and help this project stay alive and be even better.

ServiceStack Http Utils

Another library, but unlike RestSharp, ServiceStack seems to be properly maintained and keeping the pace with modern API trends. List of ServiceStack features is impressive and it certainly has various applications.

What is most useful to us here is to demonstrate how to consume an external RESTful API. ServiceStack has a specialized way of dealing with 3rd Party HTTP APIs called Http Utils.

Let us see how fetching RestSharp releases looks like using ServiceStack Http Utils first using the Json.NET parser.



public string GetReleases(string url) { var response = url.GetJsonFromUrl(webReq => { webReq.UserAgent = RequestConstants.UserAgentValue; }); return response; }

Release

public List<GitHubRelease> GetDeserializedReleases(string url) { var releases = url.GetJsonFromUrl(webReq => { webReq.UserAgent = RequestConstants.UserAgentValue; }).FromJson<List<GitHubRelease>>(); return releases; }

You can also choose to leave it to the ServiceStack parser. We can reuse theclass defined earlier in the post.As you can see, either way works fine, and you can choose whether you get the string response or deserialize it immediately.

Although ServiceStack is the last library we stumbled upon, we were pleasantly surprised how easy it was for me to use it, and I think it may become my go-to tool for dealing with APIs and services in the future.

Flurl

One of the libraries requested by many people in the comments section, and loved by many all over the internet but still gaining traction.

Flurl stands for Fluent Url Builder, which is the way the library builds its queries. For those of you not familiar with the fluent way of doing stuff, fluent simply means that the library is built in such a way that methods are chained to achieve greater readability, similar to that of human language.

To make things even easier to understand, let’s give some examples (this one is from official docs):



// Flurl will use 1 HttpClient instance per host var person = await "https://api.com" .AppendPathSegment("person") .SetQueryParams(new { a = 1, b = 2 }) .WithOAuthBearerToken("my_oauth_token") .PostJsonAsync(new { first_name = "Claire", last_name = "Underwood" }) .ReceiveJson<Person>();

You can see how the methods chain together to complete the “sentence”.

In the background, Flurl is using HttpClient or rather enhancing the HttpClient library with its own syntactic sugar. So that means Flurl is an async library and it’s good to have that in mind.

As with other advanced libraries, we can do this in two different ways:



public string GetReleases(string url) { var result = url .WithHeader(RequestConstants.UserAgent, RequestConstants.UserAgentValue) .GetJsonAsync<List<GitHubRelease>>() .Result; return JsonConvert.SerializeObject(result); }

This way is rather terrible since we are serializing a result only to deserialize it a little bit later. If you are using a library such as Flurl, you shouldn’t be doing things this way.

A better way of doing things would be:



public List<GitHubRelease> GetDeserializedReleases(string url) { var result = url .WithHeader(RequestConstants.UserAgent, RequestConstants.UserAgentValue) .GetJsonAsync<List<GitHubRelease>>() .Result; return result; }

.Result

public async Task<List<GitHubRelease>> GetDeserializedReleases(string url) { var result = await url .WithHeader(RequestConstants.UserAgent, RequestConstants.UserAgentValue) .GetJsonAsync<List<GitHubRelease>>(); return result; }

Withwe are forcing the synchronous behavior of the code. The real and intended way to use Flurl would look like this:Which shows off the full potential of the Flurl library.

If you want to learn more about how to use Flurl in different real-life scenarios, check out our Consuming GitHub API (REST) With Flurl article

In summary, it’s like advertised: easy to use, modern, readable and testable. What more can you expect of a library? To be open source? Check out: Flurl repo and contribute if you like it!

Now this one is a bit different than anything on this list so far. But this one does it a bit differently.

Let’s see how we can use DalSoft.RestClient to consume the GitHub API and then talk about what we’ve done.

First things first, you can download DalSoft.RestClient either via NuGet Package Manager by typing : Install-Package DalSoft.RestClient

or via .NET Core CLI: dotnet add package DalSoft.RestClient

Either way is fine.

Once we have our library, we can do something like this:



public string GetReleases(string url) { dynamic client = new RestClient(RequestConstants.BaseUrl, new Headers { { RequestConstants.UserAgent, RequestConstants.UserAgentValue } }); var response = client.repos.restsharp.restsharp.releases.Get().Result.ToString(); return response; }

public async Task<List<GitHubRelease>> GetDeserializedReleases(string url) { dynamic client = new RestClient(RequestConstants.BaseUrl, new Headers { { RequestConstants.UserAgent, RequestConstants.UserAgentValue } }); var response = await client.repos.restsharp.restsharp.releases.Get(); return response; }

or preferably by using DalSoft.RestClient to deserialize the response immediately while utilizing its full power:So, let’s talk about these examples a bit.

At first glance, it doesn’t seem much simpler than some other modern libraries that we’ve used.

But it comes down to the way form our requests and that’s by utilizing the dynamic nature of our RestClient. For example, our BaseUrl is https://api.github.com and we need to get to the https://api.github.com/repos/restsharp/restsharp/releases . We can do that by creating our client dynamically and then forming the Url by chaining “parts” of the Url:



await client.repos.restsharp.restsharp.releases.Get();

A pretty unique way to form a request. And a very flexible one too!

So, once we have our base Url set, we can play with different endpoints easily.

It’s also worth mentioning that JSON response we get is being automatically type-casted. As you can see in the second example, the return value of our method is Task<List<GitHubReleases>>. So the library is smart enough to cast the response to our type (relying on Json.NET). That makes our life much easier.

Besides being easy to understand and use, DalSoft.RestClient has everything a modern library should have. It is configurable, asynchronous, extensible, testable and it supports multiple platforms.

We’ve demonstrated just a small portion of the DalSoft.RestClient features. If this got you interested in using DalSoft.RestClient, head over to our article about it to learn how to use it in different scenarios or refer to official GitHub repo and documentation.

Other Options

There are a lot of other options available for your specific problems. You can use any of these libraries to consume a specific RESTful API. For example, octokit.net is used to work with GitHub API specifically, Facebook SDK is used for consuming Facebook API and there are many others for almost anything.

While these libraries are made specifically for those APIs and may be great at doing what they are meant for, their usefulness is limited because you often need to connect with more than one API in your applications. This may result in having different implementations for each one, and more dependencies which potentially leads to repetitiveness and is error-prone. The more specific the library, the less flexibility it has.

Source Code on GitHub

Source Code on GitHub

Conclusion

So, to summarize, we’ve talked about different tools you can use to consume a RESTful API. We’ve mentioned some .NET libraries that can do that like HttpWebRequest , WebClient , and HttpClient , as well as some of the amazing third-party tools like RestSharp and ServiceStack. You also gave you very short introductions to those tools and made some very simple examples to show you how you can start using them.

I consider you now at least 95% ready to consume some REST. Go forth and spread your wings, explore and find even more fancy and interesting ways to consume and connect different APIs. Sleep restfully now, you know the way 🙂