Topic Based Pub/Sub Data Bus with MassTransit

In my previous blog entry I've discussed the problem of using a single envelope-like data type in a data bus. I've presented a nice solution that uses topic-based subscriptions available in Rebus.FM framework. I've also promised to show how to do the same in MassTransit.

The problem with MassTransit is that you need a clever trick to set up all the bindings as MT doesn't support topic based subscriptions that easy. The trick is to have two layers of exchanges:

• the first layer of exchanges consists of a single exchange that is used by the publisher to put messages into the RabbitMQ
• the second layer of exchanges consists of multiple exchanges bound to the single exchange from the first layer by routing keys

and queues bound to exchanges from the second layer:

To get this, we need models

    public class MessageEnvelope
    {
        // will help to build routing keys
        public string MessageTypeName { get; set; }

        // the payload serialized to JSON
        public string Content { get; set; }

        public MessageEnvelope()
        {

        }

        public MessageEnvelope(object payload)
        {
            if (payload == null) throw new ArgumentNullException();

            this.Content         = JsonConvert.SerializeObject(payload);
            this.MessageTypeName = payload.GetType().Name;
        }

        public T GetPayload()
        {
            if (string.IsNullOrEmpty(this.Content)) throw new ArgumentException();

            return JsonConvert.DeserializeObject(this.Content);
        }
    }

    public static class EnvelopedExtensions
    {
        public static string ToJson(this object payload)
        {
            if (payload == null) throw new ArgumentNullException();

            return JsonConvert.SerializeObject(payload);
        }
    }

    public class Foo
    {
        public string Data { get; set; }
    }

    public class Bar
    {
        public string Something { get; set; }
    }

as well as the handler. Note that the handler is almost identical to the one from the previous blog entry about Rebus.FM. In fact, the only notable difference is naming of the interface you implement.

    public class Enveloped_Handler : IConsumer
    {
        private string agent { get; set; }
        public Enveloped_Handler(string agent)
        {
            this.agent = agent;
        }

        public async Task Consume(ConsumeContext context)
        {
            var message = context.Message;

            await Console.Out.WriteLineAsync($"{message.MessageTypeName} received by {this.agent}\r\n{message.ToJson()}");
        }
    }

Then, the actual code that setups the exchanges, queues and bindings and publishes messages.

   class Program
    {
        static IBusControl ConfigureActivator(string queueName, int workers = 1)
        {
            var bus = Bus.Factory.CreateUsingRabbitMq(cfg =>
            {
                var host = cfg.Host(new Uri("rabbitmq://localhost"), h =>
                {
                    h.Username("username");
                    h.Password("password");
                });

                if (queueName == "publisher")
                {
                    // take routing keys from the property
                    cfg.Send(x => x.UseRoutingKeyFormatter(context => context.Message.MessageTypeName ));
                    // publish to this exchange
                    cfg.Message(x => x.SetEntityName("MessageEnvelope"));
                    // use direct binding between the exchanges
                    cfg.Publish(x => { x.ExchangeType = ExchangeType.Direct; });
                }
                else
                {
                    cfg.ReceiveEndpoint(host, queueName, e =>
                    {
                        e.PrefetchCount = (ushort)workers;

                        switch (queueName)
                        {
                            case "subscriber1":

                                e.BindMessageExchanges = false;
                                e.Bind("MessageEnvelope", x =>
                                {
                                    x.ExchangeType = ExchangeType.Direct;
                                    x.RoutingKey = "Foo";
                                });


                                e.Consumer(() => new Enveloped_Handler("agent1"));
                                break;
                            case "subscriber2":

                                e.BindMessageExchanges = false;
                                e.Bind("MessageEnvelope", x =>
                                {
                                    x.ExchangeType = ExchangeType.Direct;
                                    x.RoutingKey = "Foo";
                                });
                                e.Bind("MessageEnvelope", x =>
                                {
                                    x.ExchangeType = ExchangeType.Direct;
                                    x.RoutingKey = "Bar";
                                });


                                e.Consumer(() => new Enveloped_Handler("agent2"));
                                break;
                        }
                        //e.con
                    });
                }
            });

            bus.Start();

            return bus;
        }

        static async Task Work()
        {
            var publisherBus   = ConfigureActivator("publisher");
            var subscriber1Bus = ConfigureActivator("subscriber1", 1);
            var subscriber2Bus = ConfigureActivator("subscriber2", 1);

            Console.WriteLine("publishing");

            await publisherBus.Publish(new MessageEnvelope( CreateFoo()) );
            await publisherBus.Publish(new MessageEnvelope( CreateBar()) );

            Console.WriteLine("published");
          
            Console.WriteLine("Press enter to quit");
            Console.ReadLine();
        }

        static Foo CreateFoo()
        {
            return new Foo()
            {
                Data = "hello foo world"
            };
        }

        static Bar CreateBar()
        {
            return new Bar()
            {
                Something = "and this is bar"
            };
        }

        static void Main(string[] args)
        {
            Work().Wait();
        } 
    }

The output of this code will be

publishing
published
Press enter to quit
Foo received by agent2
{"MessageTypeName":"Foo","Content":"{\"Data\":\"hello foo world\"}"}
Foo received by agent1
{"MessageTypeName":"Foo","Content":"{\"Data\":\"hello foo world\"}"}
Bar received by agent2
{"MessageTypeName":"Bar","Content":"{\"Something\":\"and this is bar\"}"}

If there's a simpler way to have this effect in MassTransit, in particular, if it's possible to have topic based subscriptions between exchanges and queues, with no this extra layer of exchanges, please let me know in the comments section.

Topic Based Pub/Sub Data Bus with Rebus.FM

We've been using messaging middlewares for years and it was always like "we don't want to be coupled to any specific implementation, rather we'd like to abstract the idea so that we could upgrade the internals when necessary". I remember first experiments with NServiceBus back in 2009/2010 but due to various reasons we've picked MassTransit. Using such higher-level approach has various advantages, for us, one of the thing was that we were able to migrate all deployments from MSMQ to RabbitMQ, thus gaining better performance and reliability.

One of issues that quickly turned out to be important is how the high-level engine uses the queuing subsystem. At the lower lever, where RabbitMQ operates, you have exchanges bound to queues and binary messages passed down the pipeline. At the higher level you have strongly typed contracts (classes) and strongly typed message handlers. A high-level engine needs a clean way of mapping its high level concepts to the wire level. Mass Transit does it in a straightforward manner:

Note: When a consumer is connected to a receive endpoint, the combined set of message types consumed by all of the consumers connected to the same receive endpoint are *subscribed* to the queue. The subscription method varies by broker, in the case of RabbitMQ exchange bindings are created for the message types to the exchange/queue for the receive endpoint. These subscriptions are persistent, and remain in place after the process exits. This ensures that messages published or sent that would be delivered to one of the receive endpoint consumers are saved even is the process is terminated. When the process is started, messages waiting in the queue will be delivered to the consumer(s).

What this actually means? Well, an exchange is created for each data type. In the diagram above we have two data types, Foo and Bar and thus two exchanges in RabbitMQ. Then, for each consumer, a queue is created. In the diagram we have two consumers and thus two queues.

When it comes to publishing, MassTransit just puts the message in the appropriate exchange. When it comes to subscription configuration, it uses the fanout model between exchanges and queues. In the above diagram, the Consumer 1 subscribes both message types while the Consumer 2 subscribes the Bar only. Consumers just read messages from their respective queues.

The model works great however it has its disadvantages. One of the major drawbacks here is how you set up subscriptions for consumers. It turns out that you write strongly typed handlers where the type has to be known in advance:

    public class Foo_Handler : IConsumer
    {
        public async Task Consume(ConsumeContext context)
        {
            var message = context.Message;

            // do whatever I like with and instance of Foo
        }
    }

This looks great, the handler can access the actual message in a strongly-typed fashion but ...

... all these handlers have to be either written down in an explicit way for each data type or I need a clever dynamic code generator to handle multiple data types. What's worse, my "bus" doesn't even sometimes know all the data types that are used, or rather - I don't want to recompile the data bus each time a new type appears in the family.

One of the possible approaches to the "family of data types that are not necessarily known and can change" issue involves a single "envelope-like" data type. A type that envelopes actual messages. Something like:

    // A generic envelope type
    public class MessageEnvelope
    {
        public string MessageTypeName { get; set; }

        // the actual payload serialized to JSON
        public string Content { get; set; }

        public MessageEnvelope()
        {

        }

        public MessageEnvelope(object payload)
        {
            if (payload == null) throw new ArgumentNullException();

            this.Content         = JsonConvert.SerializeObject(payload);
            this.MessageTypeName = payload.GetType().Name;
        }

        public T GetPayload()
        {
            if (string.IsNullOrEmpty(this.Content)) throw new ArgumentException();

            return JsonConvert.DeserializeObject(this.Content);
        }
    }

Suddenly, it's much easier to maintain the growing list of possible data types. I could handle types that are not known at the time the core library is compiled - the envelope will happily handle a payload of any type.

Unfortunately, while tempting, this approach has a significant disadvantage - please review the diagram above once again and imagine what happens in the RabbitMQ:

It's no longer that attractive. Now I end up with a single exchange that pushes incoming messages to all queues where agents pick up messages and have to filter them, according to the actual payload. And guess what, this slows down the pipeline! Suppose I have a lot of consumers, not two but, say, 50. A message of type Foo is published into the pipeline but since it's wrapped and is of the MessageEnvelope type, it's effectively copied to all queues (this is how the fanout works). Then, multiple consumers pick it just to realize that only few of them, maybe even a single one, subscribe this particular message. All other consumers just discard the message. Now, let's count. A single message, let's say few megabytes, copied by RabbitMQ to 50 different queues. Things go into hundred of megabytes and this is just a single message. Publish multiple messages and I have my bottleneck.

Fortunately, a solution exists that still lets me have a single envelope for all my messages but will not clog RabbitMQ with multiple messages. The solution involves topic mapping. I could still have a single exchange and multiple consumer queues. This time however, each message is published together with the topic and the binding between the exchange and queues involves explicit topis

How to set up the topic mapping in a high-level engine? Well, it's not that easy in MassTransit, unfortunately, and involves a trick I will present in another blog entry. This time I am going to show the actual code of how this particular set up works in Rebus, an engine much younger that the two introduced at the very beginning of this article. Younger doesn't mean it lacks features, though. What's nice is that it supports more transports than MassTransit (e.g. you don't even need a messaging middleware since the bare SQL Server can be used!) and supports topic based subscriptions easy.

Here's the code. We start with two dummy message types and the MessageEnvelope class presented above. A simple extension class will be used to format messages to the console.

    public class Foo
    {
        public string Data { get; set; }
    }

    public class Bar
    {
        public string Something { get; set; }
    }

    public static class EnvelopedExtensions
    {
        public static string ToJson( this object payload )
        {
            if (payload == null) throw new ArgumentNullException();

            return JsonConvert.SerializeObject(payload);
        }
    }

Now, the handler, the high-level concept of a consumer code that processes actual messages

    public class MessageEnvelope_Handler : IHandleMessages
    {
        private IBus bus { get; set; }
        private string agent { get; set; }
     
        public MessageEnvelope_Handler(IBus bus, string agent)
        {
            this.bus   = bus;
            this.agent = agent;
        }

        public async Task Handle(MessageEnvelope message)
        {
            var context = MessageContext.Current;

            await Console.Out.WriteLineAsync($"{message.MessageTypeName} received by {this.agent}\r\n{message.ToJson()}");
            
        }
    }

Then, a little configuration helper method to remove code duplication:

        static IBus ConfigureActivator(
            BuiltinHandlerActivator activator, 
            string queueName, 
            int workers = 1, 
            int parallel = 1)
        {
            var bus = Configure.With(activator)
                .Transport(t => t.UseRabbitMq("amqp://username:password@localhost", queueName))
                .Logging(l => l.ColoredConsole(LogLevel.Warn))
                .Options(conf =>
                {
                    conf.SetNumberOfWorkers(workers);
                    conf.SetMaxParallelism(parallel);
                })
                .Start();

            return bus;
        }

The actual orchestration

       static async Task Work()
        {
            using (var publisher   = new BuiltinHandlerActivator())
            using (var subscriber1 = new BuiltinHandlerActivator())
            using (var subscriber2 = new BuiltinHandlerActivator())
            {
                var publisherBus   = ConfigureActivator(publisher, "publisher");
                var subscriber1Bus = ConfigureActivator(subscriber1, "subscriber1", 2, 2);
                var subscriber2Bus = ConfigureActivator(subscriber2, "subscriber2", 2, 2);

                subscriber1.Register(() => new MessageEnvelope_Handler(subscriber1Bus, "agent1"));
                subscriber2.Register(() => new MessageEnvelope_Handler(subscriber2Bus, "agent2"));

                await subscriber1Bus.Advanced.Topics.Subscribe("Foo");
                await subscriber2Bus.Advanced.Topics.Subscribe("Foo");
                await subscriber2Bus.Advanced.Topics.Subscribe("Bar");

                Console.WriteLine("publishing");

                await publisherBus.Advanced.Topics.Publish("Foo", new MessageEnvelope(CreateFoo()));
                await publisherBus.Advanced.Topics.Publish("Bar", new MessageEnvelope(CreateBar()));

                Console.WriteLine("published");

                Console.WriteLine("Press enter to quit");
                Console.ReadLine();

            }
        }

As you can see, the Rebus' topic subscription API is used and then explicit topics are used to publish messages. Because of that, the very same message type, MessageEnvelope can be reused and still, RabbitMQ configures the binding correctly:

And this is the output of this simple demo:

publishing
published
Press enter to quit
Bar received by agent2
{"MessageTypeName":"Bar","Content":"{\"Something\":\"and this is bar\"}"}
Foo received by agent2
{"MessageTypeName":"Foo","Content":"{\"Data\":\"hello foo world\"}"}
Foo received by agent1
{"MessageTypeName":"Foo","Content":"{\"Data\":\"hello foo world\"}"}

This works as expected. The message of type Foo was handler by both consumers while Bar was handled by the second consumer only. At the price of the topic-based binding (vs the fanout binding) I have a fine-grained control over what happens in RabbitMQ and still have my single envelope type to wrap actual payloads.

Parsing SAML 1.1 (WS-Federation) tokens without the WSFam module

Ocassionally there's a scenario where a SAML token must be parsed without the WSFederationAuthentication module. Note that when the WSFam can be used, parsing is straightforward.

For us, it was one of our old applications that still can't be upgraded to .NET 4.5, because of reasons ;), and we wanted to drop the old WIF runtime (the one that targets older .NET versions). For someone else it can be another scenario, e.g. you have the SAML token as string and just want the IPrincipal out of the token.

The solution is to think of the token as it was the regular XMLDsig signed XML - the assertion node is signed and the signature's reference points back to it:

<?xml version="1.0"?>
<t:RequestSecurityTokenResponse xmlns:t="http://schemas.xmlsoap.org/ws/2005/02/trust">
  <t:Lifetime>
    <wsu:Created xmlns:wsu="http://docs.oasis-open.org/wss/2004/01/oasis-200401-wss-wssecurity-utility-1.0.xsd">2018-09-18</wsu:Created>
    <wsu:Expires xmlns:wsu="http://docs.oasis-open.org/wss/2004/01/oasis-200401-wss-wssecurity-utility-1.0.xsd">2018-09-18</wsu:Expires>
  </t:Lifetime>
  <wsp:AppliesTo xmlns:wsp="http://schemas.xmlsoap.org/ws/2004/09/policy">
    <wsa:EndpointReference xmlns:wsa="http://www.w3.org/2005/08/addressing">
      <wsa:Address>https://foo.bar/</wsa:Address>
    </wsa:EndpointReference>
  </wsp:AppliesTo>
  <t:RequestedSecurityToken>
    <saml:Assertion xmlns:saml="urn:oasis:names:tc:SAML:1.0:assertion" MajorVersion="1" MinorVersion="1" AssertionID="_assertionID" 
        Issuer="http://issuer" IssueInstant="2018-09-18">
      <saml:AttributeStatement>
        <saml:Subject>
          <saml:SubjectConfirmation>
            <saml:ConfirmationMethod>urn:oasis:names:tc:SAML:1.0:cm:bearer</saml:ConfirmationMethod>
          </saml:SubjectConfirmation>
        </saml:Subject>
        <saml:Attribute AttributeName="windowsaccountname" AttributeNamespace="http://schemas.microsoft.com/ws/2008/06/identity/claims">
          <saml:AttributeValue>username</saml:AttributeValue>
        </saml:Attribute>
      </saml:AttributeStatement>
      <ds:Signature xmlns:ds="http://www.w3.org/2000/09/xmldsig#">
        <ds:SignedInfo>
          <ds:CanonicalizationMethod Algorithm="http://www.w3.org/2001/10/xml-exc-c14n#"/>
          <ds:SignatureMethod Algorithm="http://www.w3.org/2001/04/xmldsig-more#rsa-sha256"/>
          <ds:Reference URI="#_assertionID">
            <ds:Transforms>
              <ds:Transform Algorithm="http://www.w3.org/2000/09/xmldsig#enveloped-signature"/>
              <ds:Transform Algorithm="http://www.w3.org/2001/10/xml-exc-c14n#"/>
            </ds:Transforms>
            <ds:DigestMethod Algorithm="http://www.w3.org/2001/04/xmlenc#sha256"/>
            <ds:DigestValue>digest</ds:DigestValue>
          </ds:Reference>
        </ds:SignedInfo>
        <ds:SignatureValue>signature</ds:SignatureValue>
        <KeyInfo xmlns="http://www.w3.org/2000/09/xmldsig#">
          <X509Data>
            <X509Certificate>certificate</X509Certificate>
          </X509Data>
        </KeyInfo>
      </ds:Signature>
    </saml:Assertion>
  </t:RequestedSecurityToken>
  <t:TokenType>urn:oasis:names:tc:SAML:1.0:assertion</t:TokenType>
</t:RequestSecurityTokenResponse>

What you should do is to

1. validate the signature
2. accept or reject the signature's certificate
3. parse the token to retrieve claims required to create the IPrincipal

The code is rather simple, what's interesting however is that the SignedXml class has to be inherited to have the signature validator that follows the AssertionID attribute (the default convention is that the signed node's id attribute is called just ID and the default validator just won't find the node that has the id attribute called differently):

    public class SamlSignedXml : SignedXml
    {
        public SamlSignedXml(XmlElement e) : base(e) { }

        public override XmlElement GetIdElement(XmlDocument document, string idValue)
        {
            XmlNamespaceManager mgr = new XmlNamespaceManager(document.NameTable);
            mgr.AddNamespace("trust", "http://docs.oasis-open.org/ws-sx/ws-trust/200512");
            mgr.AddNamespace("wsu", "http://docs.oasis-open.org/wss/2004/01/oasis-200401-wss-wssecurity-utility-1.0.xsd");
            mgr.AddNamespace("saml", "urn:oasis:names:tc:SAML:1.0:assertion");

            XmlElement assertionNode = 
                   (XmlElement)document.SelectSingleNode("//trust:RequestSecurityTokenResponseCollection/trust:RequestSecurityTokenResponse/"+
                                                         "trust:RequestedSecurityToken/saml:Assertion", mgr);

            if (assertionNode.Attributes["AssertionID"] != null &&
                string.Equals(assertionNode.Attributes["AssertionID"].Value, idValue, StringComparison.InvariantCultureIgnoreCase)
                )
                return assertionNode;

            return null;
        }
    }

Note that the XPath assumes the token has the RequestSecurityTokenResponseCollection in the root, make sure your tokens follow this convention (in case of a single token, the collection node can be missing and the token's root could be just RequestSecurityTokenResponse, update the code accordingly).

The validation code is then

// token is the string representation of the SAML1 token
// expectedCertThumb is the expected certificate's thumbprint
protected bool ValidateToken( string token, string expectedCertThumb, out string userName )
{
 userName = string.Empty;

 if (string.IsNullOrEmpty(token)) return false;

 var xd = new XmlDocument();
 xd.PreserveWhitespace = true;
 xd.LoadXml(token);

 XmlNamespaceManager mgr = new XmlNamespaceManager(xd.NameTable);
 mgr.AddNamespace("trust", "http://docs.oasis-open.org/ws-sx/ws-trust/200512");
 mgr.AddNamespace("wsu", "http://docs.oasis-open.org/wss/2004/01/oasis-200401-wss-wssecurity-utility-1.0.xsd");
 mgr.AddNamespace("saml", "urn:oasis:names:tc:SAML:1.0:assertion");

 // assertion
 XmlElement assertionNode = (XmlElement)xd.SelectSingleNode("//trust:RequestSecurityTokenResponseCollection/trust:RequestSecurityTokenResponse/trust:RequestedSecurityToken/saml:Assertion", mgr);

 // signature
 XmlElement signatureNode = (XmlElement)xd.GetElementsByTagName("Signature")[0];

 var signedXml = new SamlSignedXml( assertionNode );
 signedXml.LoadXml(signatureNode);

 X509Certificate2 certificate = null;
 foreach (KeyInfoClause clause in signedXml.KeyInfo)
 {
  if (clause is KeyInfoX509Data)
  {
   if (((KeyInfoX509Data)clause).Certificates.Count > 0)
   {
    certificate =
    (X509Certificate2)((KeyInfoX509Data)clause).Certificates[0];
   }
  }
 }

 // cert node missing
 if (certificate == null) return false;

 // check the signature and return the result.
 var signatureValidationResult = signedXml.CheckSignature(certificate, true);

 if (signatureValidationResult == false) return false;

 // validate cert thumb
 if ( !string.IsNullOrEmpty( expectedCertThumb ) )
 {
  if ( !string.Equals( expectedCertThumb, certificate.Thumbprint ) )
   return false;
 }

 // retrieve username

 // expires = 
 var expNode = xd.SelectSingleNode("//trust:RequestSecurityTokenResponseCollection/trust:RequestSecurityTokenResponse/trust:Lifetime/wsu:Expires", mgr );

 DateTime expireDate;

 if (!DateTime.TryParse(expNode.InnerText, out expireDate)) return false; // wrong date

 if (DateTime.UtcNow > expireDate) return false; // token too old

 // claims
 var claimNodes =                 
   xd.SelectNodes("//trust:RequestSecurityTokenResponseCollection/trust:RequestSecurityTokenResponse/trust:RequestedSecurityToken/"+
                  "saml:Assertion/saml:AttributeStatement/saml:Attribute", mgr );
 foreach ( XmlNode claimNode in claimNodes )
 {
  if ( claimNode.Attributes["AttributeName"] != null && 
              claimNode.Attributes["AttributeNamespace"] != null &&
       string.Equals( claimNode.Attributes["AttributeName"].Value, "name", StringComparison.InvariantCultureIgnoreCase ) &&   
                     string.Equals( claimNode.Attributes["AttributeNamespace"].Value, "http://schemas.xmlsoap.org/ws/2005/05/identity/claims", StringComparison.InvariantCultureIgnoreCase ) &&
         claimNode.ChildNodes.Count == 1 
      )
  {
   userName = claimNode.ChildNodes[0].InnerText;
   return true;
  }
 }

 return false;
}

A couple of comments here.

First, the XPath could possibly be shortened to reflect the possibility of a missing collection node.

Then, the code assumes there's the name claim that contains the username but it could be the windowsaccountname or maybe yet another claim type.

WCF and default serialization of requests and responses

A short story of something new we've learned about how exactly WCF serializes the data that is sent over the wire.

Introduction

Before WCF, the default way to serialize objects to XML was to use the XmlSerializer. It works and of course has its shortcomings when it comes to serialization of complex types and collections.

When WCF was introduced, a couple of new serializers were brought into the Base Class Library, including the DataContractSerializer and NetDataContractSerializer. New serializers mean new features, comparision charts are available (e.g. this one by Sebasian Krysmanski).

If you, like we did, live in a simple world where WCF just uses the new set of serializers, read on.

Usually, where both the service and the client are .NET apps, web services can be designed by writing down C# interfaces and data models first. I'd call this common approach the code first approach - you share a code between the service and the client:

// common, shared between the service and the client
[DataContract]
public class DataModel 
{
   [DataMember]
   public string Whatever { get; set; }
}

public interface IServiceContract
{
    void DoWork( DataModel model );
}

Then, the server just implements the interface and exposes the service using a service host (IIS/self-host):

[ServiceBehavior(...)]
public class ServiceImpl : IServiceContract
{
   ...
}

and the client uses the ChannelFactory or the ClientBase to easily have the proxy based on the same interface.

A case of a unit test

Working on a complex integration project involving interoperable calls between a .NET client and a Java WebService, we were faced with an approach we haven't followed often before. Instead of the usual code first approach, we were given a couple of *.WSDL/*.XSD files, which makes a valid model first approach. Given these, you use an automated tool like the xsd.exe or the newer svcutil.exe to automatically create code from models:

svcutil.exe /syncOnly /n:*,Test *.wsdl *.xsd

This approach was used, the code has been generated and someone tried to write a unit test to make sure the request body is correctly serialized so that it meets the XML structure expected at the Java's side. The unit test code first used the DataContractSerializer as we believed this is what WCF uses under the hood. The test code was basically something like:

DoWorkRequest request = new DoWorkRequest();
request.model = 

var serializer = new DataContractSerializer();
var ms = new MemoryStream();

serializer.WriteObject( ms, request );

var requestXML = Encoding.UTF8.GetString( ms.ToArray() );

Assert.....

As it turned out, the serializer's output was something like

<DoWorkRequest ....

while the server's expectation was

<DoWork ....

(note the Request suffix missing from the root's name)

The test was obviously failing. We started an investigation.

What is really going on under the hood

After a couple of different trials and errors involving other serializers and their settings, we've found something that we never manually put into the code in the code-first approach. It was the MessageContractAttribute put over the request class by the generator:

[MessageContractAttribute(WrapperName="DoWork"....]
public class DoWorkRequest {

Things started to get interesting, it looks like there's yet another serializer, not mentioned that much, that obviously respects this attribute. Googling around reveals that there is indeed yet another layer used by WCF on top of different serializers to have even more control on how your data is serialized when a web service is called. This directly leads to the TypedMessageConverter class and code snippets people already posted (e.g this one by Stanislav Dvoychenko).

A solution, finally

The solution was to rewrite the unit test to actually use the TypedMessageConverter:

var request                       = new DoWorkRequest(...);

var converter                     = TypedMessageConverter.Create( request.GetType(), "*", string.Empty, new XmlSerializerFormatAttribute());
var message                       = converter.ToMessage(request, MessageVersion.Soap11WSAddressing10);            

var writerSettings                = new XmlWriterSettings();
writerSettings.OmitXmlDeclaration = true;

var stream                        = new MemoryStream();
var writer                        = XmlWriter.Create(stream, writerSettings);

message.WriteMessage(writer);
writer.Flush();

var requsetXML = Encoding.UTF8.GetString(stream.ToArray());

which gives the exact SOAP message that can be peeked using an HTTP debugger (you can possibly unpack the soap envelope it's wrapped into in your unit test code).

A Fairy Tale of an Old Music Box

One of things I really like doing in my spare time is playing the piano we bought recently. I also decided to check whether there is some decent score writing software out there and I was really surprised to find that the software not only gets much, much better over years but also that there are even some free yet advanced apps like the MuseScore.

Anyway, this looks like my chance to write down few ideas I had on my mind for all these years since I finished my music education. And since sharing is one of nice features of the software, please enjoy one of my compositions, the first one I wrote down with MuseScore, A Fairy Tale of an Old Music Box.

A Fairy Tale of an Old Music Box

.NET 4.7.1 (and higher) no longer supports SHA1 in SignedXml

There are plenty of subtle changes between .NET 4.7.0 (and lower) and .NET 4.7.1, however one of the changes hurt us badly. It looks like the SignedXml no longer supports SHA1 as the hashing method.

What it causes is the

System.Security.Cryptography.CryptographicException : Invalid algorithm specified
...
     at System.Security.Cryptography.Utils.SignValue(SafeKeyHandle hKey, Int32 keyNumber, Int32 calgKey, Int32 calgHash, Byte[] hash, Int32 cbHash, ObjectHandleOnStack retSignature)
     at System.Security.Cryptography.Utils.SignValue(SafeKeyHandle hKey, Int32 keyNumber, Int32 calgKey, Int32 calgHash, Byte[] hash)
     at System.Security.Cryptography.RSACryptoServiceProvider.SignHash(Byte[] rgbHash, Int32 calgHash)
     at System.Security.Cryptography.Xml.SignedXml.ComputeSignature()

The resolution is to put an additional section in the app's config file that switches the use of insecure hashes on:

  <runtime>
    <AppContextSwitchOverrides value="Switch.System.Security.Cryptography.Xml.UseInsecureHashAlgorithms=true;
                                         Switch.System.Security.Cryptography.Pkcs.UseInsecureHashAlgorithms=true" />
  </runtime>

If these switches seem to be ignored (we observed this in web apps where this was put in the web.config rather than an app.config, simply replace it with the code that you put in the global app class in the Application_Start:

protected void Application_Start(object sender, EventArgs e)
{
   ...
   AppContext.SetSwitch("Switch.System.Security.Cryptography.Xml.UseInsecureHashAlgorithms", true);
   AppContext.SetSwitch("Switch.System.Security.Cryptography.Pkcs.UseInsecureHashAlgorithms", true);
}

Integracja z ePUAP - dzień bez zmiany dniem straconym

Przed weekendem 30-06/01-07 blogowałem o zmianie na środowisku testowym ePUAP, przywracającym SHA1 w trybie wymuszenia (SHA256 przestało być obsługiwane) w konstruowaniu sygnatur WS-* w żądaniach do usług integracyjnych. Napisałem też że mam nadzieję na uporządkowanie sytuacji.

Cóż, sytuacja uporządkowała się o tyle że dziś (02-07) od południa na środowisku testowym ePUAP (int.pz.gov.pl) stoi kolejna wersja, która znów wymusza SHA256 i nie obsługuje SHA1.

Pytanie retoryczne: jak długo jeszcze może trwać ten kołowrotek i jak długo poczekamy na wersję która obsłuży oba rodzaje funkcji skrótu?