Inspecting String Length Constraints in EF Core

Entity Framework Core exposes a rich representation of your database schema through its model metadata. This metadata reflects not only attributes on your entities, but also Fluent API configuration, conventions, and provider‑specific decisions.

In this post, we’ll look at a practical way to extract string length constraints from the EF Core model using:

• C#
• EF Core 8
• LINQPad 8

The goal is to surface, programmatically:

• 🧩 Entity name
• 🧱 Property name
• 🏷 Database column name
• 📏 Configured maximum string length (if any)

All of this is done without reflection and without querying database system tables.

---

Why Use EF Core Metadata?

It’s tempting to reach for reflection and scan attributes like [MaxLength] or [StringLength]. However, reflection only tells you what was declared — not what EF Core ultimately built.

EF Core metadata reflects the resolved model, which may include:

• ✅ Fluent API overrides
• ✅ Convention‑based lengths
• ✅ Provider defaults
• ✅ Shadow properties
• ✅ Mappings that never existed as CLR attributes

If EF Core generated it, the metadata knows about it.

---

Working in LINQPad 8

When you select an EF Core connection in LINQPad, LINQPad instantiates the DbContext for you. Within the query, that context instance is available via this.

This makes LINQPad an excellent environment for exploratory tooling and schema inspection.

Entry point

void Main()
{    
    var dbContext = (DbContext)this;
    
    Console.WriteLine("----------------- GET ALL THE ENTITY TYPE FIELDS/COLUMNS WITH A STRING LENGTH CONSTRAINT------------");
    
    var stringlengthConstrainedField = dbContext.GetAllStringPropertyLengths();

    foreach (var constrainedField in stringlengthConstrainedField)
    {
        Console.WriteLine($"{constrainedField.EntityName} {constrainedField.PropertyName} {constrainedField.ColumnName} {constrainedField.MaxLength}");
    }
    
    
    Console.WriteLine("-------------- GET SPECIFIC ENTITY TYPE's FIELDS/COLUMS WITH A STRING LENGTH CONSTRAINT---------------");
    
    var constrainedFieldsInSpecificTable = dbContext.GetStringPropertyLengths<Users>();

    foreach (var constrainedField in constrainedFieldsInSpecificTable)
    {
        Console.WriteLine($"{constrainedField.EntityName} {constrainedField.PropertyName} {constrainedField.ColumnName} {constrainedField.MaxLength}");
    }
}

🔎 LINQPad’s immediacy makes this kind of inspection extremely efficient.

---

DbContext Extension Methods

To keep the querying logic reusable and unobtrusive, the functionality is implemented as DbContext extension methods.

Enumerating all constrained string properties

public static class DbContextExtensions
{
    public static IEnumerable<(string EntityName, string PropertyName, string ColumnName, int? MaxLength)>
        GetAllStringPropertyLengths(this DbContext context, Type? specificEntityType = null)
    {
        var model = context.Model;
        
        IEntityType? specificEntity = null;
        
        if (specificEntityType != null)
        {
            specificEntity = model.FindEntityType(specificEntityType);
        }
        
        if (specificEntityType != null && specificEntity == null)
        {
            yield break;
        }

        var entityTypes = specificEntity == null
            ? model.GetEntityTypes()
            : new[] { specificEntity };
        
        
        foreach (var entityType in entityTypes)
        {
            var clrType = entityType.ClrType;

            foreach (var property in entityType.GetProperties())
            {
                if (property.ClrType != typeof(string))
                    continue;

                var maxLength = property.GetMaxLength();
                if (maxLength == null)
                    continue;

                var propertyName = property.Name;
                var columnName = property.GetColumnName();

                yield return (clrType.Name, propertyName, columnName, maxLength);
            }
        }
    }

🧠 This method reports what EF Core actually enforces, not merely what was declared.

---

Strongly‑typed convenience overload

    public static IEnumerable<(string EntityName, string PropertyName, string ColumnName, int? MaxLength)>
        GetStringPropertyLengths<TModel>(this DbContext context)
    {
        var stringPropertyLenghtsForType =
            GetAllStringPropertyLengths(context, typeof(TModel));

        return stringPropertyLenghtsForType;
    }
}

🎯 This keeps call‑sites expressive without duplicating logic.

---

Where This Is Useful

• ✅ Generating client‑side validation rules
• ✅ Auditing schema constraints in large models
• ✅ Verifying legacy databases after reverse engineering
• ✅ Debugging unexpected truncation or validation errors
• ✅ Building internal tooling around EF Core models

Because it relies on EF Core metadata, it remains accurate across migrations and configuration changes.

---

Closing Thoughts

EF Core already builds a comprehensive semantic model of your database schema. Exposing and inspecting that model directly is often simpler—and more reliable— than round‑tripping through reflection or database metadata tables.

LINQPad provides a particularly effective environment for this kind of work: quick, focused, and transparent.

📌 If you’re already using EF Core, you likely don’t need more tooling — you just need to look at the right layer.

C# 15 : Union types and the ApiResult Monad in .NET 11

Functional Programming in C# 15: Union Types and the ApiResult Monad

C# has been steadily absorbing ideas from functional programming — pattern matching, records, immutability. With C# 15, we get the feature that ties it all together: union types (discriminated unions). This post walks through why they matter, how they work, and how they enable a clean ApiResult<T> result monad that eliminates try/catch boilerplate and makes error handling composable.

All source code is available on GitHub: UnionTypesDemo1 and ApiResultMonad.

---

What Does Functional Programming Give Us?

Three things that make code dramatically easier to reason about:

1. Totality — every function handles every possible input. No hidden exceptions, no nulls sneaking through.
2. Composability — small pieces snap together into pipelines. You build complex behaviour by chaining simple transformations.
3. Exhaustiveness — the compiler checks that you handled all cases. Forget one? It tells you at build time, not at 3 AM in production.

Union types are the mechanism that delivers all three in C#. Let’s start with a minimal example.

---

Union Types — The IntOrBool Example

A union type is a type that holds exactly one of several named cases at a time. No inheritance hierarchies, no object boxing, no OneOf<> libraries — just a closed set of possibilities known to the compiler.

Declaring the Union

public union IntOrBool(int i, bool b)
{
    public readonly bool AsBool() => this switch
    {
        int i  => i != 0,
        bool b => b,
        null   => throw new UnreachableException()
    };

    public readonly int AsInt() => this switch
    {
        int i  => i,
        bool b => b ? 1 : 0,
        null   => throw new UnreachableException()
    };

    public override string ToString() => this switch
    {
        int i  => $"Integer: {i}",
        bool b => $"bool: {b}",
        null   => throw new UnreachableException()
    };
}

One line — public union IntOrBool(int i, bool b); — declares a type that is either an int or a bool. Each member is a case. The compiler enforces exhaustiveness on every switch expression: drop a case and you get a warning (or an error).

Using It

IntOrBool intOrBool = 42;           // holds an int case
Console.WriteLine(intOrBool);               // "Integer: 42"
Console.WriteLine(intOrBool.AsBool());      // False  (0 == false, non-zero check)
Console.WriteLine(intOrBool.AsInt());       // 42

intOrBool = true;                   // reassigned — now holds a bool case
Console.WriteLine(intOrBool);               // "bool: True"
Console.WriteLine(intOrBool.AsBool());      // True
Console.WriteLine(intOrBool.AsInt());       // 1

No cast, no wrapper allocation. The implicit conversion handles it. A single variable can be reassigned across cases — the declared type stays IntOrBool; only the runtime case changes. This is what makes union types ergonomic compared to class hierarchies.

Pattern Matching

string Describe(IntOrBool value) => value switch
{
    int i  => $"It's an integer: {i}",
    bool b => $"It's a boolean: {b}",
    null   => throw new UnreachableException()
};

Exhaustiveness is checked statically. If you add a third case to the union later, every switch site that doesn’t handle it will fail to compile. That’s the kind of safety net you get from functional languages like F# and Rust — now native in C#.

---

What Is a Monad?

A monad is a design pattern from functional programming. Think of it as a smart wrapper around a value that lets you chain operations without checking for errors at every step. The wrapper carries the result or the failure through the pipeline — you only inspect the outcome at the end.

A monad needs three things:

1. A wrapper type — something that contains a value (or an error). In our case: ApiResult<T>.
2. A way to put a value in — often called return or unit. Here: ApiResult.Ok(value).
3. A way to chain operations — Bind (also known as flatMap). Given a wrapped value and a function that returns a new wrapped value, produce the next step in the pipeline.

Classic examples: Option<T> (value may be absent), Result<T, E> (success or error). ApiResult<T> is a result monad specifically tailored for HTTP calls.

---

The ApiResult<T> Union Type

Using C# 15 union types, we define a type that can be exactly one of three cases:

public record Success<T>(T Data);
public record HttpError(int StatusCode, string Message);
public record TransportError(Exception Exception);

public readonly union ApiResult<T>(
    Success<T> success,
    HttpError httpError,
    TransportError transportLevelError
);

Case	Represents
Success<T>	HTTP 2xx with a valid deserialized body
HttpError	HTTP 4xx/5xx response
TransportError	Socket, network, timeout, or other I/O exceptions

Every ApiResult<T> is exactly one of these three — no nulls, no exceptions leaking out, no forgetting to check response.IsSuccessStatusCode. The compiler won’t let you skip a case.

---

Map — Transform the Happy Path

Map applies a function to the inner value if it is a success. Errors pass through unchanged — you stay on the “happy rail” and errors propagate automatically. This is the functional alternative to writing if (result.IsSuccess) checks at every step.

public ApiResult<TResult> Map<TResult>(Func<T, TResult> f) => Value switch
{
    Success<T> s      => new Success<TResult>(f(s.Data)),
    HttpError h        => new HttpError(h.StatusCode, h.Message),
    TransportError t   => new TransportError(t.Exception),
    _                  => new HttpError(500, "Unhandled error")
};

Usage is clean:

ApiResult<string> title = ApiResult.Ok(todo)
    .Map(t => t.Title.ToUpperInvariant());

If todo was actually an HttpError or TransportError, the lambda is never invoked — the error flows through untouched. No if, no try/catch.

---

Bind — Chain Operations That Can Fail

Bind (a.k.a. flatMap) is for sequencing operations where the next step can itself fail. It unwraps the value and hands it to a function that returns a new ApiResult<TResult>, preventing the nested ApiResult<ApiResult<T>> problem that Map would produce.

public ApiResult<TResult> Bind<TResult>(Func<T, ApiResult<TResult>> f) => Value switch
{
    Success<T> s      => f(s.Data),
    HttpError h        => new HttpError(h.StatusCode, h.Message),
    TransportError t   => new TransportError(t.Exception),
    _                  => new HttpError(500, "Unhandled error")
};

Usage:

ApiResult<string> result = ApiResult.Ok(42)
    .Bind(id => id > 0
        ? ApiResult.Ok(id.ToString())
        : ApiResult.HttpFail<string>(HttpStatusCode.BadRequest, "Invalid id"));

Map vs Bind — At a Glance

Operation	Lambda signature	Use when
Map	T → TResult	Transforming data (can’t introduce new failures)
Bind	T → ApiResult<TResult>	Next step can also fail

---

The GetJsonAsync Extension

The entry point into the monad is an extension method on HttpClient that wraps the entire HTTP call — success, HTTP errors, and transport exceptions — into an ApiResult<T>:

public static async Task<ApiResult<T>> GetJsonAsync<T>(
    this HttpClient httpClient, string url)
{
    try
    {
        using var response = await httpClient.GetAsync(url).ConfigureAwait(false);

        if (!response.IsSuccessStatusCode)
        {
            return new HttpError(
                (int)response.StatusCode,
                await response.Content.ReadAsStringAsync().ConfigureAwait(false));
        }

        await using var stream = await
            response.Content.ReadAsStreamAsync().ConfigureAwait(false);

        var val = await JsonSerializer.DeserializeAsync<T>(stream,
            new JsonSerializerOptions { PropertyNameCaseInsensitive = true })
            .ConfigureAwait(false);

        return val is not null
            ? new Success<T>(val)
            : ApiResult.HttpFail<T>(
                HttpStatusCode.UnprocessableEntity,
                $"No content or wrong content for type: {typeof(T).Name}");
    }
    catch (Exception ex)
    {
        return new TransportError(ex);
    }
}

No try/catch at the call site. Errors flow through the monad.

---

Chaining — and Why ContinueWith Is Not the Right Tool

The original example chains MapAsync and Bind like this:

var summary = await result
    .MapAsync(async todo => todo with { Title = todo.Title.ToUpperInvariant() })
    .ContinueWith(t => t.Result.Bind(todo =>
        todo.Completed
            ? ApiResult.Ok($"Done: {todo.Title}")
            : ApiResult.HttpFail<string>(HttpStatusCode.UnprocessableEntity, "Not completed")));

This works, but ContinueWith is a Task-level continuation — it belongs to TPL plumbing, not to monad composition. It has well-known pitfalls:

• It does not capture SynchronizationContext by default (unlike await).
• It swallows exceptions into AggregateException unless you explicitly unwrap.
• It forces you to reach into t.Result, mixing two abstraction levels.

The cleaner fix is to add extension methods that operate on Task<ApiResult<T>> directly, so async and sync monadic operations compose seamlessly:

public static class ApiResultTaskExtensions
{
    /// <summary>
    /// Chains a synchronous Map on an async ApiResult pipeline.
    /// </summary>
    public static async Task<ApiResult<TResult>> MapAsync<T, TResult>(
        this Task<ApiResult<T>> task, Func<T, TResult> f)
    {
        var result = await task.ConfigureAwait(false);
        return result.Map(f);
    }

    /// <summary>
    /// Chains a synchronous Bind on an async ApiResult pipeline.
    /// </summary>
    public static async Task<ApiResult<TResult>> BindAsync<T, TResult>(
        this Task<ApiResult<T>> task, Func<T, ApiResult<TResult>> f)
    {
        var result = await task.ConfigureAwait(false);
        return result.Bind(f);
    }

    /// <summary>
    /// Chains an async Bind on an async ApiResult pipeline.
    /// </summary>
    public static async Task<ApiResult<TResult>> BindAsync<T, TResult>(
        this Task<ApiResult<T>> task, Func<T, Task<ApiResult<TResult>>> f)
    {
        var result = await task.ConfigureAwait(false);
        return await result.BindAsync(f).ConfigureAwait(false);
    }
}

---

Fluent Multi-Step Chaining

With those extensions in place, you can chain Map and Bind as many times as you want — all in a single fluent pipeline, no ContinueWith in sight:

var summary = await httpClient
    .GetJsonAsync<Todo>("https://jsonplaceholder.typicode.com/todos/4")
    // Step 1 (Map): uppercase the title
    .MapAsync(todo => todo with { Title = todo.Title.ToUpperInvariant() })
    // Step 2 (Map): prefix with ID
    .MapAsync(todo => todo with { Title = $"[{todo.Id}] {todo.Title}" })
    // Step 3 (Bind): fail if not completed, otherwise produce summary string
    .BindAsync(todo => todo.Completed
        ? ApiResult.Ok($"Completed: {todo.Title}")
        : ApiResult.HttpFail<string>(HttpStatusCode.BadRequest, "Not done yet"))
    // Step 4 (Map): final formatting
    .MapAsync(msg => $">> {msg} <<");

Console.WriteLine(summary.Value switch
{
    Success<string> s  => s.Data,
    HttpError h         => $"Error {h.StatusCode}: {h.Message}",
    TransportError t    => $"Transport: {t.Exception.Message}",
    _                   => "?"
});

If any step fails — say the HTTP call returns 404, or the Bind rejects a non-completed todo — every subsequent Map and Bind is skipped automatically. The error propagates through the pipeline untouched until you pattern-match at the end. This is the “railway-oriented programming” pattern: one rail for success, one for errors, and the switch track is Bind.

What About Multiple Async Steps?

The BindAsync overload that takes Func<T, Task<ApiResult<TResult>>> lets you chain operations that are themselves async and can fail — e.g., calling a second API based on the result of the first:

var enriched = await httpClient
    .GetJsonAsync<Todo>(url)
    .MapAsync(todo => todo with { Title = todo.Title.ToUpperInvariant() })
    .BindAsync(async todo =>
    {
        // Second HTTP call — also returns ApiResult<T>
        var userResult = await httpClient
            .GetJsonAsync<User>($"https://jsonplaceholder.typicode.com/users/{todo.UserId}");

        return userResult.Map(user => $"{user.Name}: {todo.Title}");
    });

Each step composes cleanly. The pipeline reads top-to-bottom exactly like the business logic it represents.

---

Consuming the Result

At the edge of your pipeline, use a switch expression to exhaustively handle all three outcome cases:

var output = result.Value switch
{
    Success<Todo> s    => $"OK: {s.Data.Title}",
    HttpError h         => $"HTTP {h.StatusCode}: {h.Message}",
    TransportError t    => $"Transport error: {t.Exception.Message}",
    _                   => "Unknown"
};

The compiler enforces exhaustiveness. You cannot forget a case.

---

Requirements & Setup

Requirement	Value
IDE	VS Code Insiders
Extensions	C# Dev Kit + C# — both set to Pre-Release channel
Target framework	net11.0 (Update 2)
Language version	<LangVersion>preview</LangVersion> in .csproj

Union types are a C# 15 preview feature. The preview language version and preview extension channels are required for compiler support.

---

Key Takeaways

1. Union types close the gap between C# and languages like F#/Rust. A single union keyword gives you a closed, exhaustive, pattern-matchable type.
2. Monads make error handling composable. ApiResult<T> carries success or failure through a pipeline — no try/catch spaghetti, no null checks.
3. Map and Bind are the building blocks. Map transforms data. Bind sequences operations that can fail. Together they give you railway-oriented programming in idiomatic C#.
4. Avoid ContinueWith for monad chaining. Add Task<ApiResult<T>> extension methods instead. It keeps async and monadic composition at the same abstraction level and eliminates TPL pitfalls.
5. Fluent pipelines read like business logic. Chain as many Map and Bind steps as you need. Errors propagate automatically — you only handle them once, at the end.

---

Source code: UnionTypesDemo1 (IntOrBool) • ApiResultMonad

Generic EqualityComparer for classes in C#

GenericEqualityComparer

Creating support for Equality comparison of classes in C# can become repititive. In this article, we will look at a Generic equality comparer that can be used for classes to do equality comparison. Please note that we are meaning here value comparison. Structs and records support via built-in functionality such a value equality comparison. For classes, it depends on what you mean by equality comparison. Usually it means the public properties, but additional state such as private properties and fields can also be considered.

Github repo with this source code

https://github.com/toreaurstadboss/GenericEqualityComparer

A reflection-based IEqualityComparer<T> that compares two objects by their member values instead of by reference. Useful for plain C# classes that don't override Equals and GetHashCode themselves.

1 — The problem it solves

In C#, class instances are compared by reference by default. Two objects with identical data are not equal unless they are the same object in memory.

var car1 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car2 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };

Console.WriteLine(car1 == car2);        // False — different object references
Console.WriteLine(car1.Equals(car2));   // False — same reason

GenericEqualityComparer<T> solves this without touching the class itself. It uses reflection to compare each property (and optionally each field) value by value. But it also uses member expressions compiled into delegates to provide fast member value lookups. This makes the generic equality comparer used here possible to use inside collections with many items.

Lets first look at the GenericEqualityComparer source code. It is a generic class.

GenericEqualityComparer.cs

using System.Diagnostics.CodeAnalysis;
using System.Linq.Expressions;
using System.Reflection;

namespace GenericEqualityComparer.Lib
{

    /// <summary>
    /// A reflection-based <see cref="IEqualityComparer{T}"/> that compares instances of
    /// <typeparamref name="T"/> by their members rather than by reference.
    /// This is intended for use with classes that do not implement their own value-based equality semantics, and is not recommended for performance-sensitive scenarios.
    /// Types such as structs and records already have built-in value equality semantics and should not require this comparer.
    /// </summary>
    /// <typeparam name="T">The type to compare. Must be a reference type.</typeparam>
    /// <remarks>
    /// By default only public instance properties are compared. Pass the constructor flags to
    /// also include private properties and/or fields (public or private).
    /// </remarks>
    public class GenericEqualityComparer<T> : IEqualityComparer<T> where T : class
    {

        private List<Func<T, object>> _propertyGetters = new List<Func<T, object>>(); // Cache of compiled delegates for accessing the configured properties of T, used to avoid the performance overhead of reflection during comparisons.

        private List<Func<T, object>> _fieldGetters = new List<Func<T, object>>(); // Cache of compiled delegates for accessing the configured fields of T, used to avoid the performance overhead of reflection during comparisons.

        /// <summary>
        /// Initialises the comparer and builds the member accessor cache.
        /// </summary>
        /// <param name="includeFields">When <see langword="true"/>, public instance fields are included in the comparison.</param>
        /// <param name="includePrivateProperties">When <see langword="true"/>, private instance properties are included in the comparison.</param>
        /// <param name="includePrivateFields">When <see langword="true"/>, private instance fields are included in the comparison. Also enables public field comparison.</param>
        public GenericEqualityComparer(bool includeFields = false, bool includePrivateProperties = false, bool includePrivateFields = false)
        {
            CreatePropertyGetters(includePrivateProperties);
            if (includeFields || includePrivateFields)
            {
                CreateFieldGetters(includePrivateFields);
            }
        }

        private void CreatePropertyGetters(bool includePrivateProperties)
        {
            var bindingFlags = BindingFlags.Instance | BindingFlags.Public;
            if (includePrivateProperties)
            {
                bindingFlags |= BindingFlags.NonPublic;
            }

            var props = typeof(T).GetProperties(bindingFlags).Where(m => m.GetMethod != null).ToList();

            foreach (var prop in props)
            {

                //Builds the Expression<Func<T, object>> for the property getter and compiles it into a Func<T, object> delegate, which is cached for later use.
                ParameterExpression parameter = Expression.Parameter(typeof(T), "p");
                MemberExpression propertyExpression = Expression.Property(parameter, prop.Name);
                Expression boxedPropertyExpression = Expression.Convert(propertyExpression, typeof(object));
                Expression<Func<T, object>> propertyGetter = Expression.Lambda<Func<T, object>>(boxedPropertyExpression, parameter);
                _propertyGetters.Add(propertyGetter.Compile());
            }
        }

        private void CreateFieldGetters(bool includePrivateFields)
        {
            var bindingFlags = BindingFlags.Instance | BindingFlags.Public;
            if (includePrivateFields)
            {
                bindingFlags |= BindingFlags.NonPublic;
            }

            var fields = typeof(T).GetFields(bindingFlags).ToList();

            foreach (var field in fields)
            {
                // Builds the Expression<Func<T, object>> for the field getter and compiles it into a Func<T, object> delegate, which is cached for later use.
                ParameterExpression parameter = Expression.Parameter(typeof(T), "f");
                MemberExpression fieldExpression = Expression.Field(parameter, field.Name);
                Expression boxedPropertyExpression = Expression.Convert(fieldExpression, typeof(object));
                Expression<Func<T, object>> fieldGetter = Expression.Lambda<Func<T, object>>(boxedPropertyExpression, parameter);
                _fieldGetters.Add(fieldGetter.Compile());
            }

        }

        /// <summary>
        /// Determines whether <paramref name="x"/> and <paramref name="y"/> are equal by comparing
        /// each configured member in turn.
        /// </summary>
        /// <param name="x">The first object to compare.</param>
        /// <param name="y">The second object to compare.</param>
        /// <returns>
        /// <see langword="true"/> when all configured members are equal;
        /// <see langword="false"/> when any member differs, or either argument is <see langword="null"/>.
        /// </returns>
        public bool Equals(T? x, T? y)
        {
            if (x == null || y == null)
            {
                return false;
            }
            if (ReferenceEquals(x, y))
            {
                return true;
            }
            if (x.GetType() != y.GetType())
            {
                return false;
            }

            foreach (var propAccessor in _propertyGetters)
            {
                var xv = propAccessor(x);
                var yv = propAccessor(y);
                if (!xv.Equals(yv))
                {
                    return false;
                }
            }

            foreach (var fieldAccessor in _fieldGetters)
            {
                var xv = fieldAccessor(x);
                var yv = fieldAccessor(y);
                if (!xv.Equals(yv))
                {
                    return false;
                }

            }


            return true;
        }

        /// <summary>
        /// Returns an <see cref="EqualityWrapper{T}"/> for <paramref name="value"/> so that
        /// <c>==</c> and <c>!=</c> use this comparer's configured equality semantics.
        /// </summary>
        /// <param name="value">The value to wrap.</param>
        /// <returns>An <see cref="EqualityWrapper{T}"/> bound to this comparer instance.</returns>
        public EqualityWrapper<T> For(T value) => new EqualityWrapper<T>(value, this);

        /// <summary>
        /// Returns a hash code for <paramref name="obj"/> derived from the same configured members
        /// used by <see cref="Equals(T, T)"/>.
        /// </summary>
        /// <param name="obj">The object to hash.</param>
        /// <returns>A hash code consistent with the configured equality semantics.</returns>
        public int GetHashCode([DisallowNull] T obj)
        {
            int hash = 0;

            var propertyValues = _propertyGetters.Select(p => p(obj)).ToList();

            for (int i = 0; i < propertyValues.Count; i += 8)
            {
                hash = HashCode.Combine(hash,
                    propertyValues.ElementAtOrDefault(i),
                    propertyValues.ElementAtOrDefault(i + 1),
                    propertyValues.ElementAtOrDefault(i + 2),
                    propertyValues.ElementAtOrDefault(i + 3),
                    propertyValues.ElementAtOrDefault(i + 4),
                    propertyValues.ElementAtOrDefault(i + 5),
                    propertyValues.ElementAtOrDefault(i + 6));
            }

            if (_fieldGetters.Any())
            {
                var fieldValues = _fieldGetters.Select(f => f(obj)).ToList();
                for (int i = 0; i < fieldValues.Count; i += 8)
                {
                    hash = HashCode.Combine(hash,
                        fieldValues.ElementAtOrDefault(i),
                        fieldValues.ElementAtOrDefault(i + 1),
                        fieldValues.ElementAtOrDefault(i + 2),
                        fieldValues.ElementAtOrDefault(i + 3),
                        fieldValues.ElementAtOrDefault(i + 4),
                        fieldValues.ElementAtOrDefault(i + 5),
                        fieldValues.ElementAtOrDefault(i + 6));
                }
            }

            return hash;
        }

    }

}

The method For accepts a object instance of type T and returns a EqualityWrapper struct that allows the usage of operator == and !=

EqualityWrapper.cs

namespace GenericEqualityComparer.Lib;

/// <summary>
/// Pairs a value of type <typeparamref name="T"/> with a <see cref="GenericEqualityComparer{T}"/>
/// so that <c>==</c> and <c>!=</c> use the comparer's configured equality semantics instead of
/// reference equality.
/// </summary>
/// <typeparam name="T">The type of the wrapped value. Must be a reference type.</typeparam>
/// <remarks>
/// Obtain an instance via <see cref="GenericEqualityComparer{T}.For"/>:
/// <code>comparer.For(car1) == comparer.For(car2)</code>
/// </remarks>
public readonly struct EqualityWrapper<T> where T : class
{
    private readonly T _value;
    private readonly GenericEqualityComparer<T> _comparer;

    internal EqualityWrapper(T value, GenericEqualityComparer<T> comparer)
    {
        _value = value;
        _comparer = comparer;
    }

    /// <summary>
    /// Returns <see langword="true"/> when <paramref name="left"/> and <paramref name="right"/>
    /// are considered equal by their shared comparer.
    /// </summary>
    public static bool operator ==(EqualityWrapper<T> left, EqualityWrapper<T> right)
        => left._comparer.Equals(left._value, right._value);

    /// <summary>
    /// Returns <see langword="true"/> when <paramref name="left"/> and <paramref name="right"/>
    /// are not considered equal by their shared comparer.
    /// </summary>
    public static bool operator !=(EqualityWrapper<T> left, EqualityWrapper<T> right)
        => !(left == right);

    /// <inheritdoc/>
    public override bool Equals(object? obj)
        => obj is EqualityWrapper<T> other && this == other;

    /// <inheritdoc/>
    public override int GetHashCode()
        => _comparer.GetHashCode(_value);
}

2 — Quick start

2.1 Compare public properties

using GenericEqualityComparer.Lib;

var comparer = new GenericEqualityComparer<Car>();

var car1 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car2 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car3 = new Car { Make = "Toyota", Model = "Corolla", Year = 2020 };

Console.WriteLine(comparer.Equals(car1, car2));  // True  — all properties match
Console.WriteLine(comparer.Equals(car1, car3));  // False — Model differs

2.2 Use it with LINQ or collections

Because GenericEqualityComparer<T> implements IEqualityComparer<T> you can pass it directly to LINQ methods and collection APIs that accept one.

var cars = new List<Car>
{
    new Car { Make = "Toyota", Model = "Camry",   Year = 2020 },
    new Car { Make = "Toyota", Model = "Camry",   Year = 2020 }, // duplicate
    new Car { Make = "Toyota", Model = "Corolla", Year = 2021 },
};

var comparer = new GenericEqualityComparer<Car>();

// Distinct by value
var unique = cars.Distinct(comparer).ToList();  // 2 items

// GroupBy by value
var grouped = cars.GroupBy(c => c, comparer);

3 — Constructor options

The constructor accepts three optional boolean flags. All default to false.

Parameter	Type	What it includes
includeFields	bool	Public instance fields
includePrivateProperties	bool	Private instance properties
includePrivateFields	bool	Private instance fields (also enables public fields)

3.1 Include private fields

Imagine a Car class that stores a secret assembly number in a private field:

public class Car
{
    public string Make { get; set; } = string.Empty;
    public string Model { get; set; } = string.Empty;
    public int Year { get; set; }

    // private — not visible to external code
    private string _secretAssemblyNumber = string.Empty;
    public void SetSecretAssemblyNumber(string number) => _secretAssemblyNumber = number;
}

var ford1 = new Car { Make = "Ford", Model = "Focus", Year = 2022 };
var ford2 = new Car { Make = "Ford", Model = "Focus", Year = 2022 };
ford1.SetSecretAssemblyNumber("ASM-001");
ford2.SetSecretAssemblyNumber("ASM-999");  // intentionally different

// Default comparer — only sees public properties, ignores the private field
var defaultComparer = new GenericEqualityComparer<Car>();
Console.WriteLine(defaultComparer.Equals(ford1, ford2));  // True (field ignored)

// Include private fields — now the hidden difference is detected
var deepComparer = new GenericEqualityComparer<Car>(includePrivateFields: true);
Console.WriteLine(deepComparer.Equals(ford1, ford2));     // False

3.2 Include private properties

The same idea applies when a class uses a private property as an internal identifier:

public class Bicycle
{
    public string Brand { get; set; } = string.Empty;
    public string Model { get; set; } = string.Empty;

    private string FrameSerialNumber { get; set; } = string.Empty;
    public void SetFrameSerialNumber(string sn) => FrameSerialNumber = sn;
}

var bike1 = new Bicycle { Brand = "Trek", Model = "FX3" };
var bike2 = new Bicycle { Brand = "Trek", Model = "FX3" };
bike1.SetFrameSerialNumber("SN-001");
bike2.SetFrameSerialNumber("SN-999");

var defaultComparer = new GenericEqualityComparer<Bicycle>();
Console.WriteLine(defaultComparer.Equals(bike1, bike2));  // True

var deepComparer = new GenericEqualityComparer<Bicycle>(includePrivateProperties: true);
Console.WriteLine(deepComparer.Equals(bike1, bike2));     // False

4 — EqualityWrapper<T> and the == / != operators

C# doesn't allow overloading == and != on a generic type parameter T in an external comparer class. As a workaround, GenericEqualityComparer<T> exposes a For(value) method that returns an EqualityWrapper<T>. The wrapper carries both the value and the comparer, so its == and != operators delegate to the comparer instead of defaulting to reference equality.

4.1 Basic operator usage

var comparer = new GenericEqualityComparer<Car>();

var car1 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car2 = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car3 = new Car { Make = "Toyota", Model = "Corolla", Year = 2020 };

bool same      = comparer.For(car1) == comparer.For(car2);  // True
bool different = comparer.For(car1) != comparer.For(car3);  // True

4.2 With private member detection

var deepComparer = new GenericEqualityComparer<Car>(includePrivateFields: true);

var ford1 = new Car { Make = "Ford", Model = "Focus", Year = 2022 };
var ford2 = new Car { Make = "Ford", Model = "Focus", Year = 2022 };
ford1.SetSecretAssemblyNumber("ASM-001");
ford2.SetSecretAssemblyNumber("ASM-999");

if (deepComparer.For(ford1) != deepComparer.For(ford2))
{
    Console.WriteLine("Cars differ (private field detected)");
}

4.3 Consistent hashing

EqualityWrapper<T> also overrides GetHashCode() so it stays consistent with ==. This means wrapped values can be used safely as dictionary keys or in hash sets.

var comparer = new GenericEqualityComparer<Car>();
var car1     = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };
var car2     = new Car { Make = "Toyota", Model = "Camry", Year = 2020 };

int hash1 = comparer.For(car1).GetHashCode();
int hash2 = comparer.For(car2).GetHashCode();

Console.WriteLine(hash1 == hash2);  // True — equal objects, equal hashes

5 — When not to use it

Performance: The comparer uses reflection to discover members at construction time (compiled to delegates for speed), but it is still a little slower than a hand-written Equals. Avoid it in tight loops or hot paths.

• Records — C# records already have value equality built in. Use == directly.
• Structs — Same as records; value equality is the default.
• Classes you own — Prefer overriding Equals / GetHashCode or implementing IEquatable<T> for production code (due to performance). Use this comparer for tests, prototyping, or third-party types you can't modify. Or if you just would like a simple way of providing value based equality checks, but in that case you should
  really
  consider a specific implementation.

In case you work with generated code or for got a large number of POCO classes (Data transfer objects) and want to avoid using inheritance or adding value equality of your existing code, this code allows you adding value based equality, this code shown here should have you covered with a generic util class.

6 - Supported Frameworks

Please note that since we use HashCode here, supported target frameworks are netstandard 2.1 and .netcore 2.1 or later. In case you use .NET Framework 4.8 or earlier for example, you can provide a GetHashCode implementation like the following:

GetHashCode that avoids using HashCode.Combine

We can instead use two selected prime numbers and multipliers to calculate a hash of the object's propertis and fields like the following:

public int GetHashCode([DisallowNull] T obj)
{
    int hash = 0;

    var propertyValues = _propertyGetters.Select(p => p(obj)).ToList();

    for (int i = 0; i < propertyValues.Count; i += 8)
    {
        hash = Combine(hash,
            propertyValues.ElementAtOrDefault(i),
            propertyValues.ElementAtOrDefault(i + 1),
            propertyValues.ElementAtOrDefault(i + 2),
            propertyValues.ElementAtOrDefault(i + 3),
            propertyValues.ElementAtOrDefault(i + 4),
            propertyValues.ElementAtOrDefault(i + 5),
            propertyValues.ElementAtOrDefault(i + 6));
    }

    if (_fieldGetters.Any())
    {
        var fieldValues = _fieldGetters.Select(f => f(obj)).ToList();
        for (int i = 0; i < fieldValues.Count; i += 8)
        {
            hash = Combine(hash,
                fieldValues.ElementAtOrDefault(i),
                fieldValues.ElementAtOrDefault(i + 1),
                fieldValues.ElementAtOrDefault(i + 2),
                fieldValues.ElementAtOrDefault(i + 3),
                fieldValues.ElementAtOrDefault(i + 4),
                fieldValues.ElementAtOrDefault(i + 5),
                fieldValues.ElementAtOrDefault(i + 6));
        }
    }

    return hash;
}

private static int Combine(params object[] values)
{
    unchecked
    {
        int hash = 17;
        foreach (var v in values)
        {
            int h = v?.GetHashCode() ?? 0;
            hash = hash * 31 + h;
        }
        return hash;
    }
}

The strange selection of two prime numbers 17 and factor of 31 is to provide diffusion to avoid hash collisions and avoid also trouble with objects with symmetric values (a,b) equaling (b,a) is avoided
using this way of summing the hashes from each property. The HashCode.Combine allows us to avoid this.

7 — Summary

The article has presented a way to do value equality checks for instances of classes in a generic manner supporting an arbitrary number of public (and private) properties, possibly also including fields (and private fields). If you want an easy way of adding value equality checks in classes and performance allows using the expression compiled delegates shown here with a little overhead initially, you should be able to consider the code here for some scenarios. The Github Repo of mine for this source code contains a lot of tests, so the code is tested.

What you want	How
Compare public properties	new GenericEqualityComparer<T>()
Also include public fields	new GenericEqualityComparer<T>(includeFields: true)
Also include private properties	new GenericEqualityComparer<T>(includePrivateProperties: true)
Also include private fields	new GenericEqualityComparer<T>(includePrivateFields: true)
Use == / != operators	comparer.For(a) == comparer.For(b)
Use with LINQ	list.Distinct(comparer), list.GroupBy(x => x, comparer)