I'm seeing some odd behaviour after using FirstOrDefault() on a collection of structs. I've isolated it into this reproduction case. This program won't compile

using System;
using System.Linq;

namespace MyProgram {
    public class Program {
        static void Main() {

            var users = new User[] {
            new User() { UserGuid = Guid.NewGuid(), Username = "user01" },
            new User() { UserGuid = Guid.NewGuid(), Username = "user02" }

            var user = users.FirstOrDefault(u => u.Username == "user01");
            Console.WriteLine(user == default(User) ? "not found" : "found");


    public struct User {
        public Guid UserGuid;
        public string Username;

The compiler error is the rather cryptic:

Operator '==' cannot be applied to operands of type 'MyProgram.User' and 'MyProgram.User'

Changing the struct to a class works fine - but I'm at a loss as to why I can't compare a struct 'instance' to a default?

  • 2
    Because for classes it'll perform pointer comparison. For struct it's not defined (because it should do an expansive reflection comparison unless it has been defined by implementer). Think if the struct contains classes (it's possible). In that case how comparison should be done (just by reference? calling comparison operator for each class?). Think moreover if struct contains big data arrays (bad bad practice but it's allowed and under your responsability). What compiler should emit for that? For that reason IMO even a call to Equals() is pretty pretty inefficient. Nov 15, 2013 at 15:46
  • 1
    possible duplicate of Comparing two structs using ==
    – user247702
    Nov 15, 2013 at 15:48
  • Why are you using a struct instead of a class anyways? (I'm not questioning your decision, just wondering if you've thought about it and understand the differences.)
    – D Stanley
    Nov 15, 2013 at 15:49
  • @AdrianoRepetti: An array is a reference type. So, if the structs contain arrays, the == operator would just do a reference comparison on them. Dec 15, 2017 at 16:52

7 Answers 7


For classes, the == operator uses reference equality. Of course, structs are value types, so they can't be compared by reference. There is no default implementation of == for structs because memberwise comparison isn't always a valid comparison, depending on the type.

You can instead use the Object.Equals method, which does compare memberwise:

Console.WriteLine(user.Equals(default(User)) ? "not found" : "found");

Or you could just implement == to call Object.Equals:

public static bool operator ==(User lhs, User rhs)
    return lhs.Equals(rhs);

However, the default implementation of Equals for structs uses reflection, and so is very slow. It would be better to implement Equals yourself, along with == and != (and possibly GetHashCode too):

public override bool Equals(Object obj)
    return obj is User && Equals((User)obj);

public bool Equals(User other)
    return UserGuid == other.UserGuid && Username == other.Username;

public static bool operator ==(User lhs, User rhs)
    return lhs.Equals(rhs);

public static bool operator !=(User lhs, User rhs)
    return !lhs.Equals(rhs);
  • 1
    Just to add to what you said, if you override Equals, you get a compiler warning that you should also override GetHashCode.
    – rory.ap
    Oct 9, 2015 at 16:54
  • 1
    But int is a value type as well and we still use == to compare two ints. Sep 16, 2017 at 22:14
  • 2
    @rajibdotnet - the int struct is a primitive type, therefor equality is implemented by the compiler (which usually delegates to cpu integer comparison instructions), and does not depend on the class library to provide an operator== implementation. Even still, every struct is free to implement operator==, in which case, OP's problem goes away. The problem is just that structs have no default implementation, while classes do.
    – antiduh
    Oct 26, 2018 at 16:00
  • What you could do and what you should do are usually two different things. The only correct because reasonable solution is to implement IEquatable<T> (and of course also override oject.Equals and object.GetHashCode and overload ==and !=) as this also fixes other behavioral issues, for example when the type is used with collections.
    – BionicCode
    Jan 28 at 9:30

You just have to implement it:

public static bool operator == (User u1, User u2) 
   return u1.Equals(u2);  // use ValueType.Equals() which compares field-by-field.
  • This is a bad solution as it involves boxing and uses the default object.Equals implementation. This implementation uses reflection to get all fields of both compared types to compare their values one by one. The only reasonable solution is to implement IEquatable<T> as this also fixes other behavioral issues, for example when the type is used with collections.
    – BionicCode
    Jan 27 at 14:09
  • Boxing and reflection are not bad in all cases. It's perfectly fine for line of business apps where performance is not critical. (And technically it uses ValueType.Equals, not object.Equals, which uses reference equality)
    – D Stanley
    Feb 2 at 14:14
  • There are cleaner and better solutions that you can use carelessly. Your solution must at least provide an adequate Equals override to accept a User. Your answer should contain a hint that the presented solution can be extremely costly (boxing + reflection).ValueType.Equals is an override of object.Equals. The method we are talking about is defined by object. Hence, I was referring to it as object.Equals to highlight that ValueType does not define its own. The override provided by ValueType uses performance critical reflection to implement equality comparison (as I had mentioned).
    – BionicCode
    Feb 2 at 14:40
  • User is a struct, which is a ValueType, so User.Equals(User) would fall back to ValueType.Equals. I agree it uses reflection and is not as performance as one that does type-safe checking, I'm refuting your claim that it's objectively "bad" and that I must overload User.Equals. If I'm writing a line-of-business app I can simply call ValueType.Equals and move on to more valuable parts of the app. If I find that reflection is a bottleneck then I can address it. It's not always necessary to micro-optimize everything.
    – D Stanley
    Feb 2 at 14:56
  • This is not about micro optimizations. And the problem is solved without any relevant effort. You know that. My point here is that if those details had been mentioned in this answer, then people that come across actually have a choice. They would be enabled to make that decision that you are talking about. I was just leaving a comment here so that people that read this post get this valuable information so that they have a choice. My intention was to add value to your post. I came here only because this thread was referenced, so it's still relevant after 10 yrs.
    – BionicCode
    Feb 2 at 17:49

In C#, the == token is used to represent two different operators (not all languages use the same token for the two operators; VB.NET uses the tokens = and Is). One of the operators is an overloadable equality test, and is only usable in cases where either an overload is defined for both operand types, or an overload is defined for one operand type and a type to which the other operand is implicitly convertible. The other operator represents a reference-equality test, and is usable in cases where the equality-test operator would be unusable, and where one operand is a class type which derives from the other, one operand is a class type and the other is an interface type, or both operands are interface types.

The first equality-test operator cannot be used with any type (class, interface, or struct) that does not provide an explicit override for it. If the == token is used in cases where the first equality-test operator is not usable, however, C# will try to use the second operator [note that other languages like VB.NET would not do this; in VB.NET, an attempt to to use = to compare two things that don't define an equality-test overload will be an error, even if the things could be compared using the Is operator]. That second operator may be used to compare any reference type to another reference of the same type, but is not usable with structures. Since neither type of equality operator is defined for structures, the comparison is disallowed.

If one is wondering why == doesn't simply fall back upon Equals(Object), which is usable with all types, the reason is that both operands of == are subject to type coercion in ways that would prevent its behavior from matching Equals. For example, 1.0f==1.0, and 1.0==1.0f, both cast the float operand to double, but given an expression like (1.0f).Equals(1.0) the first operand can't be evaluated as anything but float. Further, if == were mapped to Equals, then it would have been necessary for C# to use a different token to represent a reference-equality test [something the language should have done anyway, but apparently didn't want to do].

  • The simple reason why the equality operator is not synonymous to the object.Equals method or why it does not simply call object.Equals is that the compiler or the language needs a default definition for equality. This is reference equality. Reference equality is evaluated by the compiler. object. Equals and ReferenceEquals internally use the equality operator == to provide a default implementation.
    – BionicCode
    Jan 28 at 8:40
  • To change the default implementation of the virtual object.Equals method you provide an override. This override is meant to define or implement more specialized rules for the equality of a particular object. The reference equality is still provided by the == operator until the type explicitly defines an overload. This way you can separate object equality from reference equality. It all makes perfect sense. It's extremely useful that this differentiation is made.
    – BionicCode
    Jan 28 at 8:40
  • This answer is wrong as it assumes that the equality operator == and object.Equals are synonymous. They are meant to provide two different definitions of equality. Depending on the operator overloads, the definition of equality can be the same. This is generally true for value types but generally wrong for reference types. If it is not clear whether a type overloads the equality operator and therefore potentially eliminates the reference equality comparison, we can always fallback to ReferenceEquals.
    – BionicCode
    Jan 28 at 9:08
  • To avoid such unexpected behavior, the equality operator of reference types should normally not be overloaded (in that it eliminates reference equality comparison).
    – BionicCode
    Jan 28 at 9:08
  • == is the token for the equality operator. This operator is well defined by the language specification. == does not represent two operators. The following statement of this answer is wrong: "One of the operators is an overloadable equality test, and is only usable in cases where either an overload is defined for both operand type[...]. The other operator represents a reference-equality test, and is usable in cases where the equality-test operator would be unusable, and where one operand is a class type which derives from the other [...]."
    – BionicCode
    Jan 28 at 9:16


public static bool IsDefault<TValue>(TValue value) => 
   EqualityComparer<TValue>.Default.Equals(value, default(TValue));

or in C# 7.1+:

public static bool IsDefault<TValue>(TValue value) =>
   EqualityComparer<TValue>.Default.Equals(value, default);

and consider implementing IEquatable<T>.

EquityComparer<T>.Default first attempts to use the IEquatable<T> interface gradually whittling down to object.Equals. This both resolves the compiler issue as well as avoid costly reflection based struct member comparisons in cases where IEquatable<T> is implemented.

Avoid implementing an == operator with the default object.Equals method, because under the hood it will use reflection as well as box your instance depending on how its called. When using EqualityComparer<T>.Default.Equals make sure your struct implements IEquatable<T> otherwise this approach will also result in reflection under the hood.

The == operator is implemented for objects and .Net types, so a custom struct will not have a default == operator implementation.

As a result of this nuance, when compiling generic equality tests, such as:

bool IsDefault<TValue> : where TValue : struct => value == default(TValue)

the compiler cannot determine the IL instruction to generate because the correct equality operator implementation cannot be determined until the generic type is resolved; however, in C# generics are resolved at run-time. So even when you do implement the == operator for a custom struct, you might still run into the issue when generics are involved.

  • If the type implements IEquatable<T> using EqualityComparer<T>.Default is useless and only adds overhead (type checking). You can simply reduce your example to: bool isDefault = value.Equals(default).
    – BionicCode
    Jan 27 at 14:01

You can overload the == operator if you want to do this

public static bool operator ==(User u1, User u2) 
        return u1.Equals(u2)

You should also override the Equals and GetHashCode()

Also if you override the ==, you will probably want to override != as well.

public static bool operator !=(User u1, User u2) 
        return !u1.Equals(u2)

When you compare two reference types, you're checking whether the references point to the same type.

But if you're dealing with value types, there are no references to compare.

You have to implement the operator yourself, and (probably) check if the value type's fields match.


Do not simply add specialized Equals overloads to your value type (like wrongfully suggested by other answers)!
Always implement IEquatable<T>.

Implementing IEquatable<T> also enables other behavioral improvements as this interface is heavily used by other .NET types like generic collections.
For example, methods like Contains, Remove or IndexOf all rely on IEquatable<T>. Same applies to EqualityComparer<T>.Default references in general (EqualityComparer<T>.Default is also internally used in collections).
If you want your value type to behave properly when used in a common manner (e.g., in collections and tables like Dictionayr<K, V>) you must implement IEquatable<T>.

The default equality operator definition checks for reference equality (compiler level). This means if the instances are the same, or in other words if two variables/operands point to the same memory object, the == operator returns true.

Because value types are always copied by value, the variable will never point to the same memory object (as copying by value means the creatin of a new memory object with a copy of each value of the old memory object).
Equality of a value type is therefore defined by comparing the values of an instance (value equality).
In this context it should be noted that it is not recommended to use object.Equals to compare for equality.
Although ValueType (the base class of e.g., struct or enum) overrides object.Equals to perform a basic value comparison for the passed in value type, object.Equals performs very bad:

  • because the parameter is defined as being of type object there incurs the cost of boxing (conversion of a value type to a reference type).
  • because the equality comparison is as general as possible, the override must use reflection to get all fields - of both participating value types (the current and the instance to compare to) to compare their values one by one.

There is no default equality operator overload for value types. Such an overload must be very slow as it had to use reflection to get all field values of a type for equality comparison (like the override of object.Equals provided by ValueType does). Given the frequency of how often the equality operator is used it makes perfect sense to let each value type define its own specialized equality comparison. This eliminates boxing and the use of reflection.

For this reason, it is recommended best practice to always let your value type implement IEquatable<T> if it qualifies for equality comparison.
This solution also avoids the expensive boxing conversion as the IEquatable<T>.Equals is now able to accept the concrete value type as argument.

When implementing IEquatable<T> it's also best practice to override object.Equals, object.GetHashCode (those overrides always go in tandem) and to overload the equality and inequality operators.
This way consistent behavior is guaranteed across the API.
Note: in the wake of overriding the default object behavior it's also best practice to override object.ToString.

An example implementation of IEquatable<T> to enable all equality comparison features could look as follows:


public readonly struct User : IEquatable<User>
  public Guid UserGuid { get; }
  public string Username { get; }

  public User(Guid userGuid, string username)
    this.UserGuid = userGuid;
    this.Username = username;

  #region IEquatable<User> implementation

  // Use ValueTuple to simplify the equality comparison implementation
  public bool Equals(User other)
    => (other.UserGuid, other.Username) == (this.UserGuid, this. Username);

  #endregion IEquatable<User> implementation
  #region object overrides

  public override bool Equals(object obj)
    => obj is User other && Equals(other);

  public override int GetHashCode()
    => HashCode.Combine(this.UserGuid, this. Username);

  // For the sake of completeness
  public override string ToString()
    => $"User: {this. Username} (ID: {this.UserGuid})";

  #endregion object overrides

  #region Operator overloads

  public static bool operator ==(User left, User right)
    => left.Equals(right);

  public static bool operator !=(User left, User right)
    => !(left == right);

  #endregion Operator overloads

Usage example

User user = new User();

// Using the equality operator
bool isDefault = user == default;

// Using the IEquatable.Equals method
bool isDefault == user.Equals(default);

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.