If you're building a .NET application, chances are high that you'll need to call an external API over HTTP.
The easy way to make HTTP requests in .NET is to use the HttpClient
to send those requests. And it's a great abstraction to work with, especially with the methods supporting JSON payloads and responses.
Unfortunately, it's easy to misuse the HttpClient
.
Port exhaustion and DNS behavior are some of the most common problems.
So here's what you need to know about working with HttpClient
:
How not to use
HttpClient
How to simplify configuration with
IHttpClientFactory
How to configure typed clients
Why you should avoid typed clients in singleton services
When to use which option
Let's dive in.
The Naive Way To Use HttpClient
The simplest way to work with the HttpClient
is to just create a new instance, set the required properties and use it to send requests.
What could possibly go wrong?
HttpClient
instances are meant to be long-lived, and reused throughout the lifetime of the application.
Each instance uses its own connection pool for isolation purposes, but also to prevent port exhaustion. If a server is under high load, and your application is constantly creating new connections, it could lead to exhausting the available ports. This will cause an exception at runtime, when trying to send a request.
So how can you avoid this?
public class GitHubService
{
private readonly GitHubSettings _settings;
public GitHubService(IOptions<GitHubSettings> settings)
{
_settings = settings.Value;
}
public async Task<GitHubUser?> GetUserAsync(string username)
{
var client = new HttpClient();
client.DefaultRequestHeaders.Add("Authorization", _settings.GitHubToken);
client.DefaultRequestHeaders.Add("User-Agent", _settings.UserAgent);
client.BaseAddress = new Uri("https://api.github.com");
GitHubUser? user = await client
.GetFromJsonAsync<GitHubUser>($"users/{username}");
return user;
}
}
The Smart Way To Create HttpClient Using IHttpClientFactory
Instead of managing the HttpClient
lifetime yourself, you can use an IHttpClientFactory
to create the HttpClient
instance.
Simply call the CreateClient
method and use the returned HttpClient
instance to send your HTTP requests.
Why is this a better approach?
The expensive part of the HttpClient
is the actual message handler - HttpMessageHandler
. Each HttpMessageHandler
has an internal HTTP connection pool that can be reused.
The IHttpClientFactory
will cache the HttpMessageHandler
and reuse it when creating a new HttpClient
instance.
An important note here is that HttpClient
instances created by IHttpClientFactory
are meant to be short-lived.
public class GitHubService
{
private readonly GitHubSettings _settings;
private readonly IHttpClientFactory _factory;
public GitHubService(
IOptions<GitHubSettings> settings,
IHttpClientFactory factory)
{
_settings = settings.Value;
_factory = factory;
}
public async Task<GitHubUser?> GetUserAsync(string username)
{
var client = _factory.CreateClient();
client.DefaultRequestHeaders.Add("Authorization", _settings.GitHubToken);
client.DefaultRequestHeaders.Add("User-Agent", _settings.UserAgent);
client.BaseAddress = new Uri("https://api.github.com");
GitHubUser? user = await client
.GetFromJsonAsync<GitHubUser>($"users/{username}");
return user;
}
}
Reducing Code Duplication With Named Clients
Using IHttpClientFactory
will solve most of the issues of manually creating an HttpClient
. However, we still need to configure the default request parameters every time we obtain a new HttpClient
from the CreateClient
method.
You can configure a named client by calling the AddHttpClient
method and passing in the desired name. The AddHttpClient
accepts a delegate that you can use to configure the default parameters on the HttpClient
instance.
services.AddHttpClient("github", (serviceProvider, client) =>
{
var settings = serviceProvider
.GetRequiredService<IOptions<GitHubSettings>>().Value;
client.DefaultRequestHeaders.Add("Authorization", settings.GitHubToken);
client.DefaultRequestHeaders.Add("User-Agent", settings.UserAgent);
client.BaseAddress = new Uri("https://api.github.com");
});
The main difference is you now have to obtain the client by passing the name of the client to CreateClient
.
But the use of the HttpClient
looks a lot simpler:
public class GitHubService
{
private readonly IHttpClientFactory _factory;
public GitHubService(IHttpClientFactory factory)
{
_factory = factory;
}
public async Task<GitHubUser?> GetUserAsync(string username)
{
var client = _factory.CreateClient("github");
GitHubUser? user = await client
.GetFromJsonAsync<GitHubUser>($"users/{username}");
return user;
}
}
Replacing Named Clients With Typed Clients
The downside of using named clients is having to resolve an HttpClient
by passing in a name every time.
There's a better way to achieve the same behavior by configuring a typed client. You can do this by calling the AddClient<TClient>
method and configuring the service that will consume the HttpClient
.
Under the hood, this is still using a named client, where the name is the same as the type name.
And this will also register GitHubService
with a transient lifetime.
services.AddHttpClient<GitHubService>((serviceProvider, client) =>
{
var settings = serviceProvider
.GetRequiredService<IOptions<GitHubSettings>>().Value;
client.DefaultRequestHeaders.Add("Authorization", settings.GitHubToken);
client.DefaultRequestHeaders.Add("User-Agent", settings.UserAgent);
client.BaseAddress = new Uri("https://api.github.com");
});
Inside of GitHubService
, you inject and use the typed HttpClient
instance which will have all of the configuration applied.
No more dealing with IHttpClientFactory
and creating HttpClient
instances manually.
public class GitHubService
{
private readonly HttpClient client;
public GitHubService(HttpClient client)
{
_client = client;
}
public async Task<GitHubUser?> GetUserAsync(string username)
{
GitHubUser? user = await client
.GetFromJsonAsync<GitHubUser>($"users/{username}");
return user;
}
}
Why You Should Avoid Typed Clients In Singleton Services
You could run into a problem if you inject a typed client into a singleton service. Since the typed client is transient, injecting it in a singleton service will cause it to be cached for the lifetime of the singleton service.
This will prevent the typed client from reacting to DNS changes.
If you want to use a typed client in a singleton service, the recommened approach is using SocketsHttpHandler
as the primary handler, and configuring the PooledConnectionLifetime
.
Since the SocketsHttpHandler
will handle connection pooling, you can disable recycling at the IHttpClientFactory
level by setting HandlerLifetime
to Timeout.InfiniteTimeSpan
.
services.AddHttpClient<GitHubService>((serviceProvider, client) =>
{
var settings = serviceProvider
.GetRequiredService<IOptions<GitHubSettings>>().Value;
client.DefaultRequestHeaders.Add("Authorization", settings.GitHubToken);
client.DefaultRequestHeaders.Add("User-Agent", settings.UserAgent);
client.BaseAddress = new Uri("https://api.github.com");
})
.ConfigurePrimaryHttpMessageHandler(() =>
{
return new SocketsHttpHandler()
{
PooledConnectionLifetime = TimeSpan.FromMinutes(15)
};
})
.SetHandlerLifetime(Timeout.InfiniteTimeSpan);
When Should You Use Which Option?
I showed you a few possible options for working with HttpClient
.
But which one should you use and when?
Microsoft was kind enough to provide us with a set of best practices and recommended use for HttpClient
.
Use a
static
or singletonHttpClient
instance with aPooledConnectionLifetime
configured, since this solves both port exhaustion and tracking DNS changesUse
IHttpClientFactory
if you want to move the configuration to one place, but remember that clients are meant to be short-livedUse a typed client if you want the
IHttpClientFactory
configurability
I prefer working with a typed client, and I'm mindful of the fact that it's configured as a transient service.
Thanks for reading, and have an awesome Saturday.
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