Visual Studio 2022, Environment/Startup

What happens when you just open the Visual Studio? It displays a solution selector where you pick up one of latests solutions. This is the default behavior. This can be changed, if you go to Options and then go to Environment/Startup page, you can change this to just show an empty environment.

People got used to it, also, it's mentioned in the documentation

The only problem is that the Environment/Startup is not there in Visual Studio 2022.

Instead, it's been moved to Environment/General, unfortunately, it's at the very bottom of the page and can easily be missed because you need to actually scroll down the page to see it

Node.js + Express + TypeScript

The Node.js + Express + Javascript is a great platform and this short tutorial shows how to add TypeScript to the picture.

Start with installing TypeScript compiler globally

npm install typescript -g

so that whenever you invoke tsc from the command line, the compiler follows your tsconfig.json and does its job. Then add the tsconfig.json

{
    "compilerOptions": {
        "lib": [
            "es2021", "DOM"
        ],
        "module": "commonjs",
        "target": "es2021",
        "strict": true,
        "esModuleInterop": true,
        "sourceMap": true                
    }
}

Note that we specifically ask the module subsystem to translate TypeScript's export/imports into node.js commonjs modules. We also turn on the esModuleInterop flag for better node.js compatibility.

Now install some typings for node and express (other typings should possibly also be installed, depending on what packages you are going to use.

npm i --save-dev @types/node
npm i --save-dev @types/express

Create the app.ts file, which will be the starting point of the app and add .vscode/launch.json with

{
    "version": "0.2.0",
    "configurations": [
        {
            "type": "pwa-node",
            "request": "launch",
            "name": "Launch Program",
            "skipFiles": [
                "<node_internals>/**"
            ],
            "program": "${workspaceFolder}\\app.ts",
            "outFiles": [
                "${workspaceFolder}/**/*.js"
            ]
        }
    ]
}

Note how the entry point (program) is set up here. Because the Typescript compiler will generate source maps, you would be able to run&debug the Typescript code.

Writing Typescript is easy now. Create an example express app

import * as http from 'http';
import express from 'express';

var app = express();

app.get('/', (req, res) => {
    res.write('hello world');
    res.end();
});

var server = http.createServer(app)

server.listen(3000);

console.log( 'started' );

Note how express is imported and how a library module (http) is imported - in both cases, there's the full intellisense support in VS Code as well as the support from the Typescript compiler.

To compile the code just invoke

tsc

once. To run the compiler in the watch mode:

tsc --watch

To show how TS modules work, create a simple module, m.ts with

class Example {
    DoWork( s: string ) : string {
        return s + ' from Example';
    }
}

export default Example;

and import it in the app.ts

import * as http from 'http';
import express from 'express';
import Example from './m';

var app = express();

app.get('/', (req, res) => {

    let e = new Example();

    res.write(e.DoWork('hello world'));
    res.end();
});

var server = http.createServer(app)

server.listen(3000);

console.log( 'started' );

Note how m.ts is compiled to m.js and also note how m.js is imported in the app.js (compiled from app.ts).

Simplest SAML1.1 (WS-Federation) Federated Authentication in .NET 6

Years ago I've blogged on how to do the WS-Fed using code only in .NET. The approach had multiple advantages over the static WSFederationAuthenticationModule (the WSFam) configured in web.config. The most important feature here is that you have the most control over what happens: how the redirect to the Identity Provider is created and how the SAML token response is consumed.

This is extremely useful in complex scenarios, e.g. in multitenant apps where tenants are configured individually or multiple identity providers are allowed or even when the federated authentication is optional at all.

.NET 6 (.NET Core) has its own way of handling WS-Federation, namely, it registers its own middleware (AddWsFederation) that can be controlled with few configuration options. However, I still feel I miss some features, like triggering the flow conditionally in a multitenant app. What I need is not yet another middleware but rather, a slightly more low-level approach following the basic principle: not use module/middleware but rather have a custom code in the logon controller/action:

if ( !IsWsFedResponse() )
{
   RedirectToIdP();
}
else
{
  var token = GetTokenFromResponse();
  var principal = ValidateToken();
  
  AuthenticateUsingPrincipal(principal);
}

Please refer to the blog entry I've linked at the top to see the approach presented there follows this.

Can we have a similar flow in .NET Core? Ignore the middleware but rather have a total control over the WS-Fed?

The answer is: sure. Since the docs are sparse and there are not-that-much examples, a decompiler is handy to just see how things are done internally so we don't rewrite anything that's already there.

So, just setup your cookie authentication and point your unauthenticated users to /Account/Logon. And then:

public class AccountController : Controller
{
	private KeyValuePair Convert(KeyValuePair pair)
	{
		return new KeyValuePair(pair.Key, pair.Value);
	}

	public async Task Logon()
	{
		WsFederationMessage wsFederationMessage = null;

		if (HttpMethods.IsPost(base.Request.Method))
		{
			var parameters = (await this.Request.ReadFormAsync()).Select(Convert);
			wsFederationMessage = new WsFederationMessage(parameters);
		}

		if (wsFederationMessage == null || !wsFederationMessage.IsSignInMessage)
		{
			var signInMessage           = new WsFederationMessage();
            
			signInMessage.IssuerAddress = "https://issuer.address/tenant/fs/ls";
			signInMessage.Wtrealm       = "https://realm.address/tenant/account/logon";

			var redirectUri = signInMessage.CreateSignInUrl();

			return Redirect(redirectUri);
		}
		else
		{
			string token = wsFederationMessage.GetToken();

			SecurityToken validatedToken;

			var tokenHandler = 
				new SamlSecurityTokenHandler()
				{
					MaximumTokenSizeInBytes = Int32.MaxValue                        
				};
			var tokenValidationParameters = new TokenValidationParameters()
			{
				AudienceValidator = (audiences, token, parameters) =>
				{
					return true;
				},
				IssuerValidator = (issuer, token, parameters) =>
				{
					return issuer;
				},
				IssuerSigningKeyValidator = (key, token, parameters) =>
				{
					if ( key is X509SecurityKey )
					{
						X509SecurityKey x509Key = (X509SecurityKey)key;

						// validate cert thumb
						// return x509Key.Certificate.Thumbprint == "alamakota";
						return true;
					}
					else
					{
						return false;
					}
				},   
				IssuerSigningKeyResolver = (token, securityToken, kid, parameters) =>
				{
					var samlToken   = (SamlSecurityToken)securityToken;
					var signature   = samlToken.Assertion.Signature;
                    
					// rewrite this to handle edge cases!
					var certificate = signature.KeyInfo.X509Data.FirstOrDefault().Certificates.FirstOrDefault();

					var x509Certificate2 = new X509Certificate2(System.Convert.FromBase64String(certificate));

					return new List()
					{
						new X509SecurityKey(x509Certificate2)
					};
				}
			};

			// if this succeeds - we have the principal
			var validatedPrincipal = tokenHandler.ValidateToken(token, tokenValidationParameters, out validatedToken);

			// we strip all claims except the user name to have a complete control over how the cookie is issued
			List claims = new List
				{
					new Claim(ClaimTypes.Name, validatedPrincipal.Identity.Name)
				};

			// create identity
			var identity = new ClaimsIdentity(claims, CookieAuthenticationDefaults.AuthenticationScheme);
			ClaimsPrincipal principal = new ClaimsPrincipal(identity);

			await this.HttpContext.SignInAsync(CookieAuthenticationDefaults.AuthenticationScheme, principal);

			return Redirect("/");
		}
	}
}

Note how the IssuerSigningKeyValidator delegate replaces the IssuerNameRegistry from the .NET Framework example (linked blog entry). Also note, that other configuration options of the TokenValidationParameters can be changed freely here on a per-request basis.

Guess6 published on GitHub

Decided to polish the code a little bit and published it on GitHub. Such small yet complete apps are a great sandboxes to test/show various programming techniques. Expect more features soon then (a redux store is the next step).

Guess6 in React - source

The game itself is published here. Here's the full source code. It's surprisingly consise, feel free to study it on your own.

// index.tsx
import React from 'react';
import ReactDOM from 'react-dom';

import App from '@/app';

/**
 * Entry point
 */
class Program {
    
    Main() {

        var app = (
                <App />
        );

        ReactDOM.render(app, document.getElementById('guess6'));
    }
}

new Program().Main();

// App.tsx
import React, { useEffect, useState } from 'react';
import Dictionary from './dictionary';
import Keyboard from './keyboard';
import WordMatch from './wordMatch';

const App = () => {

  const EXPECTEDLENGTH = 6;

  const [words, setWords] = useState<Array<string>>([]);
  const [secretWord, setSecretWord] = useState<string>('');

  function getRandomWord(Dictionary: string[]): string {
    const randomIndex = Math.floor(Math.random() * (Dictionary.length));
    return Dictionary[randomIndex].toUpperCase();
  }

  function restartGame() {
      setWords([]);
      setSecretWord(getRandomWord(Dictionary));
  }
  
  function onWordTyped( newWord: string ) {
    setWords( words => words.concat([newWord]) );   
  }

  function giveUp() {
    if ( secretWord.length == EXPECTEDLENGTH ) {
      setWords( words => words.concat( secretWord ) );
    }
  }

  useEffect( () => {
    restartGame();
  }, []);

  return <>  
    <div>
      <button className='flatButton' onClick={() => restartGame()}>NEW GAME</button>
      <button className='flatButton' onClick={() => giveUp()}>GIVE UP</button>
    </div>
    <h1>Enter {EXPECTEDLENGTH}-letter word</h1>
    <Keyboard dictionary={Dictionary} expectedLength={EXPECTEDLENGTH} onWordTyped={onWordTyped} />
    {words.map( (word, index) => <ordMatch candidate={word} secret={secretWord} key={index} />)}
  </>
};

export default App;

// Keyboard.tsx
import React, { KeyboardEvent, useEffect, useState } from 'react';

const Keyboard = ({dictionary, expectedLength, onWordTyped} : 
    {dictionary: string[] | undefined, expectedLength: number, onWordTyped: (word: string) => void}) => {

    const [message, setMessage] = useState<string>('');
    const [word, setWord]       = useState<string>('');

    const LETTERS = "ABCDEFGHIJKLMNOPQRSTUVWXYZ";
    const QWERTY  = "QWERTYUIOP";
    const ASDF    = "ASDFGHJKL";
    const ZXCV    = "ZXCVBNM";

    function appendLetter(letter: string) {
        if ( word.length < expectedLength ) {
            setWord( w => w + letter );
            setMessage('');
        }
    }

    function clearWord() {
        setWord('');
        setMessage('');
    }

    function tryAcceptWord() {
        if ( word.length != expectedLength ) {
            setMessage(`Expected ${expectedLength} characters, got ${word.length} so far`);
            return;
        } 
        
        if ( dictionary !== undefined && dictionary.map( w => w.toUpperCase() ).indexOf( word ) < 0 ) {
            setMessage(`Word ${word} not in dictionary`);
            return;
        }
      
        onWordTyped(word);
        setWord('');
    }

    return <div>
        <div>
            <input className='keyboardInput' value={word} readOnly />
        </div>
        <div className='firstRow'>
            {QWERTY.split('').map( (letter) => <button className='letterButton flatButton'  
              onClick={() => appendLetter(letter)} key={letter}>{letter}</button> )}
        </div>
        <div className='secondRow'>
            {ASDF.split('').map( (letter) => <button className='letterButton flatButton'  
              onClick={() => appendLetter(letter)} key={letter}>{letter}</button> )}
            <button className='flatButton' onClick={() => clearWord()}>DEL</button>
        </div>
        <div className='thirdRow'>
            {ZXCV.split('').map( (letter) => <button className='letterButton flatButton'  
              onClick={() => appendLetter(letter)} key={letter}>{letter}</button> )}
            <button className='flatButton' onClick={() => tryAcceptWord()}>ENTER</button>
        </div>
        <div>{message}</div>
    </div>;
}

export default Keyboard;

// WordMatch.tsx
import React from 'react';

const WordMatch = ({candidate, secret} : {candidate: string, secret: string}) => {

    if ( candidate.length != secret.length ) {
        throw new Error('candidate and secret word must have same length');
    }

    type  letterState = 'USED' | undefined;
    const letterStates: Array<letterState> = Array<letterState>(candidate.length);

    function getLetterClass( index: number ) : string {        
        // match
        if ( secret[index] == candidate[index] ) {
            letterStates[index] = 'USED';
            return 'letter letterMatch';
        }
        // possible
        for ( let i=0; i<secret.length; i++ ) {
            if ( secret[i] == candidate[index] &&
                 letterStates[i] == undefined 
                ) {
                letterStates[i] = 'USED';
                return 'letter letterPossible';
            }
        }
        // none
        return 'letter letterWrong';
    }

    return <div>
        {candidate.split('').map( (letter, index) => 
            <span className={getLetterClass(index)} key={index}>{letter}</span>
        )}
    </div>;
}

export default WordMatch;

// Dictionary.ts
// https://eslforums.com/6-letter-words/

const Dictionary: Array<string> = [
"abacus",
// the rest of the dictionary here
"zoning"
];

export default Dictionary;

Guess6 in React

WinForms Dependency Injection in .NET6

This entry is motivated by the discussion in one of StackOverflow's questions, the How to use dependency injection in WinForms. A correct answer by Reza Aghaei shows how the container can be created and used, however, one of drawbacks of Reza's answer is that the container is used directly, which makes this approach fall under the Service Locator antipattern.

I've decided then to create a follow up and show one of possible correct solutions. This solution is based on the Local Factory pattern.

We'll start with a form factory

public interface IFormFactory
{
	Form1 CreateForm1();
	Form2 CreateForm2();
}

public class FormFactory : IFormFactory
{
	static IFormFactory _provider;

	public static void SetProvider( IFormFactory provider )
	{
		_provider = provider;
	}

	public Form1 CreateForm1()
	{
		return _provider.CreateForm1();
	}

	public Form2 CreateForm2()
	{
		return _provider.CreateForm2();
	}
}

From now on, this factory is the primary client's interface to creating forms. The client code is no longer supposed to just call

var form1 = new Form1();

No, it's forbidden. Instead, the client should always call

var form1 = new FormFactory().CreateForm1();

(and similarily for other forms).

Note that while the factory is implemented, it doesn't do anything on its own! Instead it delegates the creation to a somehow mysterious provider which has to be injected into the factory. The idea behind this is that the provider will be injected, once, in the Composition Root which is a place in the code, close to the startup, and very high in the application stack so that all dependencies can be resolved there. So, the form factory doesn't need to know what provider will be ultimately injected into it.

This approach has a significant advantage - depending on actual requirements, different providers can be injected, for example you could have a DI-based provider (we'll write it in a moment) for an actual application and a stub provider for unit tests.

Anyway, let's have a form with a dependency:

public partial class Form1 : Form
{
	private IHelloWorldService _service;

	public Form1(IHelloWorldService service)
	{
		InitializeComponent();

		this._service = service;
	}
}

This form depends on a service and the service will be provided by the constructor. If the Form1 needs to create another form, Form2, it does it it a way we already discussed:

var form2 = new FormFactory().CreateForm2();

Things become more complicated, though, when a form needs not only dependant services but also, just some free parameters (strings, ints etc.). Normally, you'd have a constructor

public Form2( string something, int somethingElse ) ...

but now you need something more like

public Form2( ISomeService service1, IAnotherService service2, string something, int somethingElse ) ...

This is something we should really take a look into. Look once again, a real-life form possibly needs

1. some parameters that are resolved by the container
2. other parameters that should be provided by the form creator (not known by the container!).

How do we handle that?

To have a complete example, let's then modify the form factory

public interface IFormFactory
{
	Form1 CreateForm1();
	Form2 CreateForm2(string something);
}

public class FormFactory : IFormFactory
{
	static IFormFactory _provider;

	public static void SetProvider( IFormFactory provider )
	{
		_provider = provider;
	}

	public Form1 CreateForm1()
	{
		return _provider.CreateForm1();
	}

	public Form2 CreateForm2(string something)
	{
		return _provider.CreateForm2(something);
	}
}

And let's see how forms are defined

public partial class Form1 : Form
{
	private IHelloWorldService _service;

	public Form1(IHelloWorldService service)
	{
		InitializeComponent();

		this._service = service;
	}

	private void button1_Click( object sender, EventArgs e )
	{
		var form2 = new FormFactory().CreateForm2("foo");
		form2.Show();
	}
}

public partial class Form2 : Form
{
	private IHelloWorldService _service;
	private string _something;

	public Form2(IHelloWorldService service, string something)
	{
		InitializeComponent();

		this._service = service;
		this._something = something;

		this.Text = something;
	}
}

Can you see a pattern here?

1. whenever a form (e.g. Form1) needs only dependand services, it's creation method in the FormFactory is empty (dependencies will be resolved by the container).
2. whenever a form (e.g. Form2) needs dependand services and other free parameters, it's creation method in the FormFactory contains a list of arguments corresponding to these free parameters (service dependencies will be resolved by the container)

Now finally to the Composition Root. Let's start with the service

public interface IHelloWorldService
{
	string DoWork();
}

public class HelloWorldServiceImpl : IHelloWorldService
{
	public string DoWork()
	{
		return "hello world service::do work";
	}
}

Note that while the interface is supposed to be somewhere down in the stack (to be recognized by everyone), the implementation is free to be provided anywhere (forms don't need reference to the implementation!). Then, follows the starting code where the form factory is finally provided and the container is set up

internal static class Program
{
	[STAThread]
	static void Main()
	{
		var formFactory = CompositionRoot();

		ApplicationConfiguration.Initialize();
		Application.Run(formFactory.CreateForm1());
	}

	static IHostBuilder CreateHostBuilder()
	{
		return Host.CreateDefaultBuilder()
			.ConfigureServices((context, services) => {
				services.AddTransient<IHelloWorldService, HelloWorldServiceImpl>();
				services.AddTransient<Form1>();
				services.AddTransient<Func<string,Form2>>(
					container =>
						something =>
						{
							var helloWorldService = 
                                container.GetRequiredService<IHelloWorldService>();
							return new Form2(helloWorldService, something);
						});
			});
	}

	static IFormFactory CompositionRoot()
	{
		// host
		var hostBuilder = CreateHostBuilder();
		var host = hostBuilder.Build();

		// container
		var serviceProvider = host.Services;

		// form factory
		var formFactory = new FormFactoryImpl(serviceProvider);
		FormFactory.SetProvider(formFactory);

		return formFactory;
	}
}

public class FormFactoryImpl : IFormFactory
{
	private IServiceProvider _serviceProvider;

	public FormFactoryImpl(IServiceProvider serviceProvider)
	{
		this._serviceProvider = serviceProvider;
	}

	public Form1 CreateForm1()
	{
		return _serviceProvider.GetRequiredService<Form1>();
	}

	public Form2 CreateForm2(string something)
	{
		var _form2Factory = _serviceProvider.GetRequiredService<Func<string, Form2>>();
		return _form2Factory( something );
	}
}

First note how the container is created with Host.CreateDefaultBuilder, an easy task. Then note how services are registered and how forms are registered among other services.

This is straightforward for forms that don't have any dependencies, it's just

services.AddTransient<Form1>();

However, if a form needs both services and free parameters, it's registered as ... form creation function, a Func of any free parameters that returns actual form. Take a look at this

services.AddTransient<Func<string,Form2>>(
	container =>
		something =>
		{
			var helloWorldService = container.GetRequiredService<IHelloWorldService>();
			return new Form2(helloWorldService, something);
		});

That's clever. We register a form factory function using one of registration mechanisms that itself uses a factory function (yes, a factory that uses another factory, a Factception. Feel free to take a short break if you feel lost here). Our registered function, the Func<string, Form2> has a single parameter, the something (that corresponds to the free parameter of the form constructor) but its other dependencies are resolved ... by the container (which is what we wanted).

This is why the actual form factory needs to pay attention of what it resolves. A simple form is resolved as follows

return _serviceProvider.GetRequiredService<Form1>();

where the other is resolved in two steps. We first resolve the factory function and then use the creation's method parameter to feed it to the function:

var _form2Factory = _serviceProvider.GetRequiredService<Func<string, Form2>>();
return _form2Factory( something );

And, that's it. Whenever a form is created, is either

new FormFactory().CreateForm1();

for "simple" forms (with service dependencies only) or just

new FormFactory().CreateForm2("foo");

for forms that need both service dependncies and other free parameters.

Happy coding. A simple excercise for you is to provide a different form factory, a factory that doesn't use a container but composes dependencies directly, for example for unit tests.