---
title: "SE-0185: Synthesizing `Equatable` and `Hashable` conformance"
framework: swift-evolution
role: article
path: swift-evolution/0185-synthesize-equatable-hashable
---

# SE-0185: Synthesizing `Equatable` and `Hashable` conformance

* Proposal: [SE-0185](0185-synthesize-equatable-hashable.md)
* Author: [Tony Allevato](https://github.com/allevato)
* Review Manager: [Chris Lattner](https://github.com/lattner)
* Status: **Implemented (Swift 4.1)**
* Implementation: [apple/swift#9619](https://github.com/apple/swift/pull/9619)
* Decision Notes: [Rationale](https://forums.swift.org/t/accepted-se-0185-synthesizing-equatable-and-hashable-conformance/6493)

## Introduction

Developers have to write large amounts of boilerplate code to support equatability and hashability of complex types. This proposal offers a way for the compiler to automatically synthesize conformance to `Equatable` and `Hashable` to reduce this boilerplate, in a subset of scenarios where generating the correct implementation is known to be possible.

Swift-evolution thread: [Universal Equatability, Hashability, and Comparability ](https://forums.swift.org/t/universal-equatability-hashability-and-comparability/1718)

## Motivation

Building robust types in Swift can involve writing significant boilerplate code to support hashability and equatability. By eliminating the complexity for the users, we make `Equatable`/`Hashable` types much more appealing to users and allow them to use their own types in contexts that require equatability and hashability with no added effort on their part (beyond declaring the conformance).

Equality is pervasive across many types, and for each one users must implement the `==` operator such that it performs a fairly rote memberwise equality test. As an example, an equality test for a basic `struct` is fairly uninteresting:

```swift struct Person: Equatable {   static func == (lhs: Person, rhs: Person) -> Bool {     return lhs.firstName == rhs.firstName &&            lhs.lastName == rhs.lastName &&            lhs.birthDate == rhs.birthDate &&            ...   } } ```

What's worse is that this operator must be updated if any properties are added, removed, or changed, and since it must be manually written, it's possible to get it wrong, either by omission or typographical error.

Likewise, hashability is necessary when one wishes to store a type in a `Set` or use one as a multi-valued `Dictionary` key. Writing high-quality, well-distributed hash functions is not trivial so developers may not put a great deal of thought into them—especially as the number of properties increases—not realizing that their performance could potentially suffer as a result. And as with equality, writing it manually means there is the potential for it to not only be inefficient, but incorrect as well.

In particular, the code that must be written to implement equality for `enum`s is quite verbose:

```swift enum Token: Equatable {   case string(String)   case number(Int)   case lparen   case rparen      static func == (lhs: Token, rhs: Token) -> Bool {     switch (lhs, rhs) {     case (.string(let lhsString), .string(let rhsString)):       return lhsString == rhsString     case (.number(let lhsNumber), .number(let rhsNumber)):       return lhsNumber == rhsNumber     case (.lparen, .lparen), (.rparen, .rparen):       return true     default:       return false     }   } } ```

Crafting a high-quality hash function for this `enum` would be similarly inconvenient to write.

Swift already derives `Equatable` and `Hashable` conformance for a small subset of `enum`s: those for which the cases have no associated values (which includes enums with raw types). Two instances of such an `enum` are equal if they are the same case, and an instance's hash value is its ordinal:

```swift enum Foo {   case zero, one, two }

let x = (Foo.one == Foo.two)  // evaluates to false let y = Foo.one.hashValue     // evaluates to 1 ```

Likewise, conformance to `RawRepresentable` is automatically derived for `enum`s with a raw type, and the recently approved `Encodable`/`Decodable` protocols also support synthesis of their operations when possible. Since there is  precedent for synthesized conformances in Swift, we propose extending it to these fundamental protocols.

## Proposed solution

In general, we propose that a type synthesize conformance to `Equatable`/`Hashable` if all of its members are `Equatable`/`Hashable`. We describe the specific conditions under which these conformances are synthesized below, followed by the details of how the conformance requirements are implemented.

### Requesting synthesis is opt-in

Users must _opt-in_ to automatic synthesis by declaring their type as `Equatable` or `Hashable` without implementing any of their requirements. This conformance must be part of the original type declaration or in an extension in the same file (to ensure that `private` and `fileprivate` members can be accessed from the extension).

Any type that declares such conformance and satisfies the conditions below will cause the compiler to synthesize an implementation of `==`/`hashValue` for that type.

Making the synthesis opt-in—as opposed to automatic derivation without an explicit declaration—provides a number of benefits:

* The syntax for opting in is natural; there is no clear analogue in Swift   today for having a type opt out of a feature.

* It requires users to make a conscious decision about the public API surfaced   by their types. Types cannot accidentally "fall into" conformances that the   user does not wish them to; a type that does not initially support `Equatable`   can be made to at a later date, but the reverse is a breaking change.

* The conformances supported by a type can be clearly seen by examining   its source code; nothing is hidden from the user.

* We reduce the work done by the compiler and the amount of code generated   by not synthesizing conformances that are not desired and not used.

* As will be discussed later, explicit conformance significantly simplifies   the implementation for recursive types.

There is one exception to this rule: the current behavior will be preserved that `enum` types with cases that have no associated values (including those with raw values) conform to `Equatable`/`Hashable` _without_ the user explicitly declaring those conformances. While this does add some inconsistency to `enum`s under this proposal, changing this existing behavior would be source-breaking. The question of whether such `enum`s should be required to opt-in as well can be revisited at a later date if so desired.

Synthesis is supported in same-file extensions to ensure that generic types can synthesize a conditional conformance, since the properties may only satisfy the requirements for synthesis (see below) with extra bounds:

``` swift struct Bad<T>: Equatable { // synthesis not possible, T is not Equatable     var x: T }

struct Good<T> {     var x: T } extension Good: Equatable where T: Equatable {} // synthesis works, T is Equatable ```

### Overriding synthesized conformances

Any user-provided implementations of `==` or `hashValue` will override the default implementations that would be provided by the compiler.

### Conditions where synthesis is allowed

For brevity, let `P` represent either the protocol `Equatable` or `Hashable` in the descriptions below.

#### Synthesized requirements for `enum`s

For an `enum`, synthesis of `P`'s requirements is based on the conformances of its cases' associated values. Computed properties are not considered.

The following rules determine whether `P`'s requirements can be synthesized for an `enum`:

* The compiler does **not** synthesize `P`'s requirements for an `enum` with no   cases because it is not possible to create instances of such types.

* The compiler synthesizes `P`'s requirements for an `enum` with one or more   cases if and only if all of the associated values of all of its cases conform   to `P`.

#### Synthesized requirements for `struct`s

For a `struct`, synthesis of `P`'s requirements is based on the conformances of **only** its stored instance properties. Neither static properties nor computed instance properties (those with custom getters) are considered.

The following rules determine whether `P`'s requirements can be synthesized for a `struct`:

* The compiler trivially synthesizes `P`'s requirements for a `struct` with *no*   stored properties. (All instances of a `struct` with no stored properties can   be considered equal and hash to the same value if the user opts in to this.)

* The compiler synthesizes `P`'s requirements for a `struct` with one or more   stored properties if and only if all of the types of all of its stored   properties conform to `P`.

### Considerations for recursive types

By making the synthesized conformances opt-in, recursive types have their requirements fall into place with no extra effort. In any cycle belonging to a recursive type, every type in that cycle must declare its conformance explicitly. If a type does so but cannot have its conformance synthesized because it does not satisfy the conditions above, then it is simply an error for _that_ type and not something that must be detected earlier by the compiler in order to reason about _all_ the other types involved in the cycle. (On the other hand, if conformance were implicit, the compiler would have to fully traverse the entire cycle to determine eligibility, which would make implementation much more complex).

### Implementation details

An `enum T: Equatable` that satisfies the conditions above will receive a synthesized implementation of `static func == (lhs: T, rhs: T) -> Bool` that returns `true` if and only if `lhs` and `rhs` are the same case and have payloads that are memberwise-equal.

An `enum T: Hashable` that satisfies the conditions above will receive a synthesized implementation of `var hashValue: Int { get }` that uses an unspecified hash function<sup>†</sup> to compute the hash value by incorporating the case's ordinal (i.e., definition order) followed by the hash values of its associated values as its terms, also in definition order.

A `struct T: Equatable` that satisfies the conditions above will receive a synthesized implementation of `static func == (lhs: T, rhs: T) -> Bool` that returns `true` if and only if `lhs.x == rhs.x` for all stored properties `x` in `T`. If the `struct` has no stored properties, this operator simply returns `true`.

A `struct T: Hashable` that satisfies the conditions above will receive a synthesized implementation of `var hashValue: Int { get }` that uses an unspecified hash function<sup>†</sup> to compute the hash value by incorporating the hash values of the fields as its terms, in definition order. If the `struct` has no stored properties, this property evaluates to a fixed value not specified here.

<sup>†</sup> The choice of hash function is left as an implementation detail, not a fixed part of the design; as such, users should not depend on specific characteristics of its behavior. The most likely implementation would call the standard library's `_mixInt` function on each member's hash value and then combine them with exclusive-or (`^`), which mirrors the way `Collection` types are hashed today.

## Source compatibility

By making the conformance opt-in, this is a purely additive change that does not affect existing code. We also avoid source-breaking changes by not changing the behavior for `enum`s with no associated values, which will continue to implicitly conform to `Equatable` and `Hashable` even without explicitly declaring the conformance.

## Effect on ABI stability

This feature is purely additive and does not change ABI.

## Effect on API resilience

N/A.

## Alternatives considered

In order to realistically scope this proposal, we considered but ultimately deferred the following items, some of which could be proposed additively in the future.

### Synthesis for `class` types and tuples

We do not synthesize conformances for `class` types. The conditions above become more complicated in inheritance hierarchies, and equality requires that `static func ==` be implemented in terms of an overridable instance method for it to be dispatched dynamically. Even for `final` classes, the conditions are not as clear-cut as they are for value types because we have to take superclass behavior into consideration. Finally, since objects have reference identity, memberwise equality may not necessarily imply that two instances are equal.

We do not synthesize conformances for tuples at this time. While this would nicely round out the capabilities of value types, allow the standard library to remove the hand-crafted implementations of `==` for up-to-arity-6 tuples, and allow those types to be used in generic contexts where `Equatable` conformance is required, adding conformances to non-nominal types would require additional work.

### Omitting fields from synthesized conformances

Some commenters have expressed a desire to tag certain properties of a `struct` from being included in automatically generated equality tests or hash value computations. This could be valuable, for example, if a property is merely used as an internal cache and does not actually contribute to the "value" of the instance. Under the rules above, if this cached value was equatable, a user would have to override `==` and `hashValue` and provide their own implementations to ignore it.

Such a feature, which could be implemented with an attribute such as `@transient`, would likely also play a role in other protocols like `Encodable`/`Decodable`. This could be done as a purely additive change on top of this proposal, so we propose not doing this at this time.

### Implicit derivation

An earlier draft of this proposal made derived conformances implicit (without declaring `Equatable`/`Hashable` explicitly). This has been changed because&mdash;in addition to the reasons mentioned earlier in the proposal&mdash;`Encodable`/`Decodable` provide a precedent for having the conformance be explicit. More importantly, however, determining derivability for recursive types is _significantly more difficult_ if conformance is implicit, because it requires examining the entire dependency graph for a particular type and to properly handle cycles in order to decide if the conditions are satisfied.

### Support for `Comparable`

The original discussion thread also included `Comparable` as a candidate for automatic generation. Unlike equatability and hashability, however, comparability requires an ordering among the members being compared. Automatically using the definition order here might be too surprising for users, but worse, it also means that reordering properties in the source code changes the code's behavior at runtime. (This is true for hashability as well if a multiplicative hash function is used, but hash values are not intended to be persistent and reordering the terms does not produce a significant _behavioral_ change.)

## Acknowledgments

Thanks to Joe Groff for spinning off the original discussion thread, Jose Cheyo Jimenez for providing great real-world examples of boilerplate needed to support equatability for some value types, Mark Sands for necromancing the swift-evolution thread that convinced me to write this up, and everyone on swift-evolution since then for giving me feedback on earlier drafts.