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A few days ago I had a curious thought: With all these different technologies that the ASP.NET stack has to offer, what's the fastest technology overall to return raw data for a server request? When I started this it was mere curiosity rather than a real practical need or result. Different tools are used for different problems and so performance differences are to be expected. But still I was curious to see how the various technologies performed relative to each orher just for raw throughput of the request getting to the endpoint and back out to the client with as little processing in the actual endpoint logic as possible (aka Hello World).

I want to clarify that this is merely an informal test for my own curiosity and I'm sharing the results and process here because I thought it was interesting. It's been a long while since I've done any sort of perf testing on ASP.NET, mainly because I've not had extremely heavy load requirements and because overall ASP.NET performs very well even for fairly high loads so that often it's not that critical to test for load performance. And that's a good thing!

This post is not meant to make a point or even come to a conclusion which tech is better, but just to act as a reference to help understand some of the differences in perf and give a starting point to play around with yourself. I've included the code for this simple project, so you can play with it and maybe add a few additional tests for different things if you like:

I looked at these technologies:

ASP.NET Web API ASP.NET MVC WebForms ASP.NET WebPages ASMX AJAX Services (couldn't get AJAX/JSON to run on IIS8 ) WCF Rest Raw ASP.NET HttpHandlers

It's quite a mixed bag, of course and the technologies target different types of development. What started out as mere curiosity turned into a bit of a head scratcher as the results were sometimes surprising.

First test: Raw Throughput

The first thing I tested was raw throughput for the various technologies. This is the least practical test of course since you're unlikely to ever create the equivalent of a 'Hello World' request in a real life application. The idea here is to measure how much time a 'NOP' request takes to return data to the client. So for this request I create the simplest Hello World request that I could come up for each tech.

Http Handler

The first is the lowest level approach which is an HTTP handler.

public class Handler : IHttpHandler { public void ProcessRequest( HttpContext context) { context.Response.ContentType = "text/plain" ; context.Response.Write( "Hello World. Time is: " + DateTime .Now.ToString()); } public bool IsReusable { get { return true ; } } }

WebForms

Next I added a couple of ASPX pages - one using CodeBehind and one using only a markup page.

The CodeBehind page simple does this in CodeBehind without any markup in the ASPX page:

public partial class HelloWorld_CodeBehind : System.Web.UI. Page { protected void Page_Load( object sender, EventArgs e) { Response.Write( "Hello World. Time is: " + DateTime .Now.ToString() ); Response.End(); } }

while the Markup page only contains some static output via an expression:

<% @ Page Language ="C#" AutoEventWireup ="false" CodeBehind ="HelloWorld_Markup.aspx.cs" Inherits ="AspNetFrameworksPerformance.HelloWorld_Markup" %> Hello World. Time is <% = DateTime .Now %>

ASP.NET WebPages

WebPages is the freestanding Razor implementation of ASP.NET. Here's the simple HelloWorld.cshtml page:

Hello World @ DateTime .Now

WCF REST

WCF REST was the token REST implementation for ASP.NET before WebAPI and the inbetween step from ASP.NET AJAX. I'd like to forget that this technology was ever considered for production use, but I'll include it here. Here's an OperationContract class:

[ ServiceContract (Namespace = "" )] [ AspNetCompatibilityRequirements (RequirementsMode = AspNetCompatibilityRequirementsMode .Allowed)] public class WcfService { [ OperationContract ] [ WebGet ] public Stream HelloWorld() { var data = Encoding .Unicode.GetBytes( "Hello World" + DateTime .Now.ToString()); var ms = new MemoryStream (data); // Add your operation implementation here return ms; } }

WCF REST can return arbitrary results by returning a Stream object and a content type. The code above turns the string result into a stream and returns that back to the client.



ASP.NET AJAX (ASMX Services)

I also wanted to test ASP.NET AJAX services because prior to WebAPI this is probably still the most widely used AJAX technology for the ASP.NET stack today.

Unfortunately I was completely unable to get this running on my Windows 8 machine. Visual Studio 2012 removed adding of ASP.NET AJAX services, and when I tried to manually add the service and configure the script handler references it simply did not work - I always got a SOAP response for GET and POST operations. No matter what I tried I always ended up getting XML results even when explicitly adding the ScriptHandler. So, I didn't test this (but the code is there - you might be able to test this on a Windows 7 box).

ASP.NET MVC

Next up is probably the most popular ASP.NET technology at the moment: MVC. Here's the small controller:

public class MvcPerformanceController : Controller { public ActionResult Index() { return View(); } public ActionResult HelloWorldCode() { return new ContentResult () { Content = "Hello World. Time is: " + DateTime .Now.ToString() }; } }

ASP.NET WebAPI

Next up is WebAPI which looks kind of similar to MVC. Except here I have to use a StringContent result to return the response:

public class WebApiPerformanceController : ApiController { [ HttpGet ] public HttpResponseMessage HelloWorldCode() { return new HttpResponseMessage () { Content = new StringContent ( "Hello World. Time is: " + DateTime .Now.ToString(), Encoding .UTF8, "text/plain" ) }; } }

Testing

Take a minute to think about each of the technologies… and take a guess which you think is most efficient in raw throughput. The fastest should be pretty obvious, but the others - maybe not so much.

The testing I did is pretty informal since it was mainly to satisfy my curiosity - here's how I did this: I used Apache Bench (ab.exe) from a full Apache HTTP installation to run and log the test results of hitting the server. ab.exe is a small executable that lets you hit a URL repeatedly and provides counter information about the number of requests, requests per second etc. ab.exe and the batch file are located in the \LoadTests folder of the project.

An ab.exe command line looks like this:

ab.exe -n100000 -c20 http://localhost/aspnetperf/api/HelloWorld

which hits the specified URL 100,000 times with a load factor of 20 concurrent requests. This results in output like this:

It's a great way to get a quick and dirty performance summary. Run it a few times to make sure there's not a large amount of varience. You might also want to do an IISRESET to clear the Web Server. Just make sure you do a short test run to warm up the server first - otherwise your first run is likely to be skewed downwards. ab.exe also allows you to specify headers and provide POST data and many other things if you want to get a little more fancy. Here all tests are GET requests to keep it simple.

I ran each test:

100,000 iterations

Load factor of 20 concurrent connections

IISReset before starting

A short warm up run for API and MVC to make sure startup cost is mitigated

Here is the batch file I used for the test:

IISRESET REM make sure you add REM C:\Program Files (x86)\Apache Software Foundation\Apache2.2\bin REM to your path so ab.exe can be found REM Warm up ab.exe -n100 -c20 http://localhost/aspnetperf/MvcPerformance/HelloWorldJson

ab.exe -n100 -c20 http://localhost/aspnetperf/api/HelloWorldJson ab.exe -n100 -c20 http://localhost/AspNetPerf/WcfService.svc/HelloWorld ab.exe -n100000 -c20 http://localhost/aspnetperf/handler.ashx > handler.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/HelloWorld_CodeBehind.aspx > AspxCodeBehind.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/HelloWorld_Markup.aspx > AspxMarkup.txt ab.exe -n100000 -c20 http://localhost/AspNetPerf/WcfService.svc/HelloWorld > Wcf.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/MvcPerformance/HelloWorldCode > Mvc.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/api/HelloWorld > WebApi.txt

I ran each of these tests 3 times and took the average score for Requests/second, with the machine otherwise idle. I did see a bit of variance when running many tests but the values used here are the medians. Part of this has to do with the fact I ran the tests on my local machine - result would probably more consistent running the load test on a separate machine hitting across the network.

I ran these tests locally on my laptop which is a Dell XPS with quad core Sandibridge I7-2720QM @ 2.20ghz and a fast SSD drive on Windows 8. CPU load during tests ran to about 70% max across all 4 cores (IOW, it wasn't overloading the machine). Ideally you can try running these tests on a separate machine hitting the local machine. If I remember correctly IIS 7 and 8 on client OSs don't throttle so the performance here should be representative of what you can expect in a live scenario.

Results

Ok, let's cut straight to the chase. Below are the results from the tests…

The chart shows Requests per second for the different technologies. It's not surprising that the handler was fastest. But it was a bit surprising to me that the next fastest was WebForms and especially Web Forms with markup over a CodeBehind page. WebPages also fared fairly well. MVC and WebAPI are a little slower and the slowest by far is WCF REST (which again I find surprising).

As mentioned at the start the raw throughput tests are not overly practical as they don't test scripting performance for the HTML generation engines or serialization performances of the data engines. All it really does is give you an idea of the raw throughput for the technology from time of request to reaching the endpoint and returning minimal text data back to the client which indicates full round trip performance.

But it's still interesting to see that Web Forms performs better in throughput than either MVC, WebAPI or WebPages. It'd be interesting to try this with a few pages that actually have some parsing logic on it, but that's beyond the scope of this throughput test.

But what's also amazing about this test is the sheer amount of traffic that a laptop computer is handling. Even the slowest tech managed 5700 requests a second, which is one hell of a lot of requests if you extrapolate that out over a 24 hour period. Remember these are not static pages, but dynamic requests that are being served.

Another test - JSON Data Service Results

The second test I used a JSON result from several of the technologies. I didn't bother running WebForms and WebPages through this test since that doesn't make a ton of sense to return data from the them (OTOH, returning text from the APIs didn't make a ton of sense either :-)

In these tests I have a small Person class that gets serialized and then returned to the client. The Person class looks like this:

public class Person { public Person() { Id = 10; Name = "Rick" ; Entered = DateTime .Now; } public int Id { get ; set ; } public string Name { get ; set ; } public DateTime Entered { get ; set ; } }

Here are the updated handler classes that use Person:

Handler

public class Handler : IHttpHandler { public void ProcessRequest( HttpContext context) { var action = context.Request.QueryString[ "action" ]; if (action == "json" ) JsonRequest(context); else TextRequest(context); } public void TextRequest( HttpContext context) { context.Response.ContentType = "text/plain" ; context.Response.Write( "Hello World. Time is: " + DateTime .Now.ToString()); } public void JsonRequest( HttpContext context) { var json = JsonConvert .SerializeObject( new Person (), Formatting .None); context.Response.ContentType = "application/json" ; context.Response.Write(json); } public bool IsReusable { get { return true ; } } }

This code adds a little logic to check for a action query string and route the request to an optional JSON result method. To generate JSON, I'm using the same JSON.NET serializer (JsonConvert.SerializeObject) used in Web API to create the JSON response.

WCF REST

[ ServiceContract (Namespace = "" )] [ AspNetCompatibilityRequirements (RequirementsMode = AspNetCompatibilityRequirementsMode .Allowed)] public class WcfService { [ OperationContract ] [ WebGet ] public Stream HelloWorld() { var data = Encoding .Unicode.GetBytes( "Hello World " + DateTime .Now.ToString()); var ms = new MemoryStream (data); // Add your operation implementation here return ms; } [ OperationContract ] [ WebGet (ResponseFormat= WebMessageFormat .Json,BodyStyle= WebMessageBodyStyle .WrappedRequest)] public Person HelloWorldJson() { // Add your operation implementation here return new Person (); } }

For WCF REST all I have to do is add a method with the Person result type.

ASP.NET MVC

public class MvcPerformanceController : Controller { // // GET: /MvcPerformance/ public ActionResult Index() { return View(); } public ActionResult HelloWorldCode() { return new ContentResult () { Content = "Hello World. Time is: " + DateTime .Now.ToString() }; } public JsonResult HelloWorldJson() { return Json( new Person (), JsonRequestBehavior .AllowGet); } }

For MVC all I have to do for a JSON response is return a JSON result. ASP.NET internally uses JavaScriptSerializer.

ASP.NET WebAPI

public class WebApiPerformanceController : ApiController { [ HttpGet ] public HttpResponseMessage HelloWorldCode() { return new HttpResponseMessage () { Content = new StringContent ( "Hello World. Time is: " + DateTime .Now.ToString(), Encoding .UTF8, "text/plain" ) }; } [ HttpGet ] public Person HelloWorldJson() { return new Person (); } [ HttpGet ] public HttpResponseMessage HelloWorldJson2() { var response = new HttpResponseMessage ( HttpStatusCode .OK); response.Content = new ObjectContent < Person >( new Person (), GlobalConfiguration .Configuration.Formatters.JsonFormatter); return response; } }

Testing and Results

To run these data requests I used the following ab.exe commands:

REM JSON RESPONSES ab.exe -n100000 -c20 http://localhost/aspnetperf/Handler.ashx?action=json > HandlerJson.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/MvcPerformance/HelloWorldJson > MvcJson.txt ab.exe -n100000 -c20 http://localhost/aspnetperf/api/HelloWorldJson > WebApiJson.txt ab.exe -n100000 -c20 http://localhost/AspNetPerf/WcfService.svc/HelloWorldJson > WcfJson.txt

The results from this test run are a bit interesting in that the WebAPI test improved performance significantly over returning plain string content.

Here are the results:

The performance for each technology drops a little bit except for WebAPI which is up quite a bit! From this test it appears that WebAPI is actually significantly better performing returning a JSON response, rather than a plain string response.

Snag with Apache Benchmark and 'Length Failures'

I ran into a little snag with Apache Benchmark, which was reporting failures for my Web API requests when serializing. As the graph shows performance improved significantly from with JSON results from 5580 to 6530 or so which is a 15% improvement (while all others slowed down by 3-8%).

However, I was skeptical at first because the WebAPI test reports showed a bunch of errors on about 10% of the requests. Check out this report:

Notice the Failed Request count. What the hey? Is WebAPI failing on roughly 10% of requests when sending JSON?

Turns out: No it's not! But it took some sleuthing to figure out why it reports these failures. At first I thought that Web API was failing, and so to make sure I re-ran the test with Fiddler attached and runiisning the ab.exe test by using the -X switch:

ab.exe -n100 -c10 -X localhost:8888 http://localhost/aspnetperf/api/HelloWorldJson

which showed that indeed all requests where returning proper HTTP 200 results with full content.

However ab.exe was reporting the errors. After some closer inspection it turned out that the dates varying in size altered the response length in dynamic output.

For example: these two results:

{"Id":10,"Name":"Rick","Entered":"2012-09-04T10:57:24.841926-10:00"}

{"Id":10,"Name":"Rick","Entered":"2012-09-04T10:57:24.8519262-10:00"}

are different in length for the number which results in 68 and 69 bytes respectively. The same URL produces different result lengths which is what ab.exe reports. I didn't notice at first bit the same is happening when running the ASHX handler with JSON.NET result since it uses the same serializer that varies the milliseconds.

Moral: You can typically ignore Length failures in Apache Benchmark and when in doubt check the actual output with Fiddler. Note that the other failure values are accurate though.

Another interesting Side Note: Perf drops over Time

As I was running these tests repeatedly I was finding that performance steadily dropped from a startup peak to a 10-15% lower stable level. IOW, with Web API I'd start out with around 6500 req/sec and in subsequent runs it keeps dropping until it would stabalize somewhere around 5900 req/sec occasionally jumping lower. For these tests this is why I did the IIS RESET and warm up for individual tests. This is a little puzzling. Looking at Process Monitor while the test are running memory very quickly levels out as do handles and threads, on the first test run. Subsequent runs everything stays stable, but the performance starts going downwards. This applies to all the technologies - Handlers, Web Forms, MVC, Web API - curious to see if others test this and see similar results.

Doing an IISRESET then resets everything and performance starts off at peak again…

Summary

As I stated at the outset, these were informal to satiate my curiosity not to prove that any technology is better or even faster than another. While there clearly are differences in performance the differences (other than WCF REST which was by far the slowest and the raw handler which was by far the highest) are relatively minor, so there is no need to feel that any one technology is a runaway standout in raw performance. Choosing a technology is about more than pure performance but also about the adequateness for the job and the easy of implementation. The strengths of each technology will make for any minor performance difference we see in these tests.

However, to me it's important to get an occasional reality check and compare where new technologies are heading. Often times old stuff that's been optimized and designed for a time of less horse power can utterly blow the doors off newer tech and simple checks like this let you compare. Luckily we're seeing that much of the new stuff performs well even in V1.0 which is great.

To me it was very interesting to see Web API perform relatively badly with plain string content, which originally led me to think that Web API might not be properly optimized just yet. For those that caught my Tweets late last week regarding WebAPI's slow responses was with String content which is in fact considerably slower. Luckily where it counts with serialized JSON and XML WebAPI actually performs better. But I do wonder what would make generic string content slower than serialized code?

This stresses another point: Don't take a single test as the final gospel and don't extrapolate out from a single set of tests. Certainly Twitter can make you feel like a fool when you post something immediate that hasn't been fleshed out a little more <blush>. Egg on my face. As a result I ended up screwing around with this for a few hours today to compare different scenarios. Well worth the time…

I hope you found this useful, if not for the results, maybe for the process of quickly testing a few requests for performance and charting out a comparison. Now onwards with more serious stuff…

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