//===--- Mirror.swift -----------------------------------------------------===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors // Licensed under Apache License v2.0 with Runtime Library Exception // // See https://swift.org/LICENSE.txt for license information // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors // //===----------------------------------------------------------------------===// // FIXME: ExistentialCollection needs to be supported before this will work // without the ObjC Runtime. #if SWIFT_ENABLE_REFLECTION /// A representation of the substructure and display style of an instance of /// any type. /// /// A mirror describes the parts that make up a particular instance, such as /// the instance's stored properties, collection or tuple elements, or its /// active enumeration case. Mirrors also provide a "display style" property /// that suggests how this mirror might be rendered. /// /// Playgrounds and the debugger use the `Mirror` type to display /// representations of values of any type. For example, when you pass an /// instance to the `dump(_:_:_:_:)` function, a mirror is used to render that /// instance's runtime contents. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(reflecting: p)) /// // Prints "▿ Point /// // - x: 21 /// // - y: 30" /// /// To customize the mirror representation of a custom type, add conformance to /// the `CustomReflectable` protocol. public struct Mirror { /// The static type of the subject being reflected. /// /// This type may differ from the subject's dynamic type when this mirror /// is the `superclassMirror` of another mirror. public let subjectType: Any.Type /// A collection of `Child` elements describing the structure of the /// reflected subject. public let children: Children /// A suggested display style for the reflected subject. public let displayStyle: DisplayStyle? internal let _makeSuperclassMirror: () -> Mirror? internal let _defaultDescendantRepresentation: _DefaultDescendantRepresentation /// Creates a mirror that reflects on the given instance. /// /// If the dynamic type of `subject` conforms to `CustomReflectable`, the /// resulting mirror is determined by its `customMirror` property. /// Otherwise, the result is generated by the language. /// /// If the dynamic type of `subject` has value semantics, subsequent /// mutations of `subject` will not observable in `Mirror`. In general, /// though, the observability of mutations is unspecified. /// /// - Parameter subject: The instance for which to create a mirror. public init(reflecting subject: Any) { if case let customized as CustomReflectable = subject { self = customized.customMirror } else { self = Mirror(internalReflecting: subject) } } /// Creates a mirror representing the given subject with a specified /// structure. /// /// You use this initializer from within your type's `customMirror` /// implementation to create a customized mirror. /// /// If `subject` is a class instance, `ancestorRepresentation` determines /// whether ancestor classes will be represented and whether their /// `customMirror` implementations will be used. By default, the /// `customMirror` implementation of any ancestors is ignored. To prevent /// bypassing customized ancestors, pass /// `.customized({ super.customMirror })` as the `ancestorRepresentation` /// parameter when implementing your type's `customMirror` property. /// /// - Parameters: /// - subject: The instance to represent in the new mirror. /// - children: The structure to use for the mirror. The collection /// traversal modeled by `children` is captured so that the resulting /// mirror's children may be upgraded to a bidirectional or random /// access collection later. See the `children` property for details. /// - displayStyle: The preferred display style for the mirror when /// presented in the debugger or in a playground. The default is `nil`. /// - ancestorRepresentation: The means of generating the subject's /// ancestor representation. `ancestorRepresentation` is ignored if /// `subject` is not a class instance. The default is `.generated`. public init( _ subject: Subject, children: C, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) where C.Element == Child { self.subjectType = Subject.self self._makeSuperclassMirror = Mirror._superclassIterator( subject, ancestorRepresentation) self.children = Children(children) self.displayStyle = displayStyle self._defaultDescendantRepresentation = subject is CustomLeafReflectable ? .suppressed : .generated } /// Creates a mirror representing the given subject with unlabeled children. /// /// You use this initializer from within your type's `customMirror` /// implementation to create a customized mirror, particularly for custom /// types that are collections. The labels of the resulting mirror's /// `children` collection are all `nil`. /// /// If `subject` is a class instance, `ancestorRepresentation` determines /// whether ancestor classes will be represented and whether their /// `customMirror` implementations will be used. By default, the /// `customMirror` implementation of any ancestors is ignored. To prevent /// bypassing customized ancestors, pass /// `.customized({ super.customMirror })` as the `ancestorRepresentation` /// parameter when implementing your type's `customMirror` property. /// /// - Parameters: /// - subject: The instance to represent in the new mirror. /// - unlabeledChildren: The children to use for the mirror. The collection /// traversal modeled by `unlabeledChildren` is captured so that the /// resulting mirror's children may be upgraded to a bidirectional or /// random access collection later. See the `children` property for /// details. /// - displayStyle: The preferred display style for the mirror when /// presented in the debugger or in a playground. The default is `nil`. /// - ancestorRepresentation: The means of generating the subject's /// ancestor representation. `ancestorRepresentation` is ignored if /// `subject` is not a class instance. The default is `.generated`. public init( _ subject: Subject, unlabeledChildren: C, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) { self.subjectType = Subject.self self._makeSuperclassMirror = Mirror._superclassIterator( subject, ancestorRepresentation) let lazyChildren = unlabeledChildren.lazy.map { Child(label: nil, value: $0) } self.children = Children(lazyChildren) self.displayStyle = displayStyle self._defaultDescendantRepresentation = subject is CustomLeafReflectable ? .suppressed : .generated } /// Creates a mirror representing the given subject using a dictionary /// literal for the structure. /// /// You use this initializer from within your type's `customMirror` /// implementation to create a customized mirror. Pass a dictionary literal /// with string keys as `children`. Although an *actual* dictionary is /// arbitrarily-ordered, when you create a mirror with a dictionary literal, /// the ordering of the mirror's `children` will exactly match that of the /// literal you pass. /// /// If `subject` is a class instance, `ancestorRepresentation` determines /// whether ancestor classes will be represented and whether their /// `customMirror` implementations will be used. By default, the /// `customMirror` implementation of any ancestors is ignored. To prevent /// bypassing customized ancestors, pass /// `.customized({ super.customMirror })` as the `ancestorRepresentation` /// parameter when implementing your type's `customMirror` property. /// /// - Parameters: /// - subject: The instance to represent in the new mirror. /// - children: A dictionary literal to use as the structure for the /// mirror. The `children` collection of the resulting mirror may be /// upgraded to a random access collection later. See the `children` /// property for details. /// - displayStyle: The preferred display style for the mirror when /// presented in the debugger or in a playground. The default is `nil`. /// - ancestorRepresentation: The means of generating the subject's /// ancestor representation. `ancestorRepresentation` is ignored if /// `subject` is not a class instance. The default is `.generated`. public init( _ subject: Subject, children: KeyValuePairs, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) { self.subjectType = Subject.self self._makeSuperclassMirror = Mirror._superclassIterator( subject, ancestorRepresentation) let lazyChildren = children.lazy.map { Child(label: $0.0, value: $0.1) } self.children = Children(lazyChildren) self.displayStyle = displayStyle self._defaultDescendantRepresentation = subject is CustomLeafReflectable ? .suppressed : .generated } /// A mirror of the subject's superclass, if one exists. public var superclassMirror: Mirror? { return _makeSuperclassMirror() } } extension Mirror { /// Representation of descendant classes that don't override /// `customMirror`. /// /// Note that the effect of this setting goes no deeper than the /// nearest descendant class that overrides `customMirror`, which /// in turn can determine representation of *its* descendants. internal enum _DefaultDescendantRepresentation { /// Generate a default mirror for descendant classes that don't /// override `customMirror`. /// /// This case is the default. case generated /// Suppress the representation of descendant classes that don't /// override `customMirror`. /// /// This option may be useful at the root of a class cluster, where /// implementation details of descendants should generally not be /// visible to clients. case suppressed } /// The representation to use for ancestor classes. /// /// A class that conforms to the `CustomReflectable` protocol can control how /// its mirror represents ancestor classes by initializing the mirror /// with an `AncestorRepresentation`. This setting has no effect on mirrors /// reflecting value type instances. public enum AncestorRepresentation { /// Generates a default mirror for all ancestor classes. /// /// This case is the default when initializing a `Mirror` instance. /// /// When you use this option, a subclass's mirror generates default mirrors /// even for ancestor classes that conform to the `CustomReflectable` /// protocol. To avoid dropping the customization provided by ancestor /// classes, an override of `customMirror` should pass /// `.customized({ super.customMirror })` as `ancestorRepresentation` when /// initializing its mirror. case generated /// Uses the nearest ancestor's implementation of `customMirror` to create /// a mirror for that ancestor. /// /// Other classes derived from such an ancestor are given a default mirror. /// The payload for this option should always be `{ super.customMirror }`: /// /// var customMirror: Mirror { /// return Mirror( /// self, /// children: ["someProperty": self.someProperty], /// ancestorRepresentation: .customized({ super.customMirror })) // <== /// } case customized(() -> Mirror) /// Suppresses the representation of all ancestor classes. /// /// In a mirror created with this ancestor representation, the /// `superclassMirror` property is `nil`. case suppressed } /// An element of the reflected instance's structure. /// /// When the `label` component in not `nil`, it may represent the name of a /// stored property or an active `enum` case. If you pass strings to the /// `descendant(_:_:)` method, labels are used for lookup. public typealias Child = (label: String?, value: Any) /// The type used to represent substructure. /// /// When working with a mirror that reflects a bidirectional or random access /// collection, you may find it useful to "upgrade" instances of this type /// to `AnyBidirectionalCollection` or `AnyRandomAccessCollection`. For /// example, to display the last twenty children of a mirror if they can be /// accessed efficiently, you write the following code: /// /// if let b = AnyBidirectionalCollection(someMirror.children) { /// for element in b.suffix(20) { /// print(element) /// } /// } public typealias Children = AnyCollection /// A suggestion of how a mirror's subject is to be interpreted. /// /// Playgrounds and the debugger will show a representation similar /// to the one used for instances of the kind indicated by the /// `DisplayStyle` case name when the mirror is used for display. public enum DisplayStyle: Sendable { case `struct`, `class`, `enum`, tuple, optional, collection case dictionary, `set` } internal static func _noSuperclassMirror() -> Mirror? { return nil } @_semantics("optimize.sil.specialize.generic.never") @inline(never) internal static func _superclassIterator( _ subject: Subject, _ ancestorRepresentation: AncestorRepresentation ) -> () -> Mirror? { if let subjectClass = Subject.self as? AnyClass, let superclass = _getSuperclass(subjectClass) { switch ancestorRepresentation { case .generated: return { Mirror(internalReflecting: subject, subjectType: superclass) } case .customized(let makeAncestor): return { let ancestor = makeAncestor() if superclass == ancestor.subjectType || ancestor._defaultDescendantRepresentation == .suppressed { return ancestor } else { return Mirror(internalReflecting: subject, subjectType: superclass, customAncestor: ancestor) } } case .suppressed: break } } return Mirror._noSuperclassMirror } } /// A type that explicitly supplies its own mirror. /// /// You can create a mirror for any type using the `Mirror(reflecting:)` /// initializer, but if you are not satisfied with the mirror supplied for /// your type by default, you can make it conform to `CustomReflectable` and /// return a custom `Mirror` instance. public protocol CustomReflectable { /// The custom mirror for this instance. /// /// If this type has value semantics, the mirror should be unaffected by /// subsequent mutations of the instance. var customMirror: Mirror { get } } /// A type that explicitly supplies its own mirror, but whose /// descendant classes are not represented in the mirror unless they /// also override `customMirror`. public protocol CustomLeafReflectable: CustomReflectable {} //===--- Addressing -------------------------------------------------------===// /// A protocol for legitimate arguments to `Mirror`'s `descendant` /// method. /// /// Do not declare new conformances to this protocol; they will not /// work as expected. public protocol MirrorPath { // FIXME(ABI)#49 (Sealed Protocols): this protocol should be "non-open" and // you shouldn't be able to create conformances. } extension Int: MirrorPath {} extension String: MirrorPath {} extension Mirror { internal struct _Dummy: CustomReflectable { internal init(mirror: Mirror) { self.mirror = mirror } internal var mirror: Mirror internal var customMirror: Mirror { return mirror } } /// Returns a specific descendant of the reflected subject, or `nil` if no /// such descendant exists. /// /// Pass a variadic list of string and integer arguments. Each string /// argument selects the first child with a matching label. Each integer /// argument selects the child at that offset. For example, passing /// `1, "two", 3` as arguments to `myMirror.descendant(_:_:)` is equivalent /// to: /// /// var result: Any? = nil /// let children = myMirror.children /// if let i0 = children.index( /// children.startIndex, offsetBy: 1, limitedBy: children.endIndex), /// i0 != children.endIndex /// { /// let grandChildren = Mirror(reflecting: children[i0].value).children /// if let i1 = grandChildren.firstIndex(where: { $0.label == "two" }) { /// let greatGrandChildren = /// Mirror(reflecting: grandChildren[i1].value).children /// if let i2 = greatGrandChildren.index( /// greatGrandChildren.startIndex, /// offsetBy: 3, /// limitedBy: greatGrandChildren.endIndex), /// i2 != greatGrandChildren.endIndex /// { /// // Success! /// result = greatGrandChildren[i2].value /// } /// } /// } /// /// This function is suitable for exploring the structure of a mirror in a /// REPL or playground, but is not intended to be efficient. The efficiency /// of finding each element in the argument list depends on the argument /// type and the capabilities of the each level of the mirror's `children` /// collections. Each string argument requires a linear search, and unless /// the underlying collection supports random-access traversal, each integer /// argument also requires a linear operation. /// /// - Parameters: /// - first: The first mirror path component to access. /// - rest: Any remaining mirror path components. /// - Returns: The descendant of this mirror specified by the given mirror /// path components if such a descendant exists; otherwise, `nil`. public func descendant( _ first: MirrorPath, _ rest: MirrorPath... ) -> Any? { var result: Any = _Dummy(mirror: self) for e in [first] + rest { let children = Mirror(reflecting: result).children let position: Children.Index if case let label as String = e { position = children.firstIndex { $0.label == label } ?? children.endIndex } else if let offset = e as? Int { position = children.index(children.startIndex, offsetBy: offset, limitedBy: children.endIndex) ?? children.endIndex } else { _preconditionFailure( "Someone added a conformance to MirrorPath; that privilege is reserved to the standard library") } if position == children.endIndex { return nil } result = children[position].value } return result } } #else // SWIFT_ENABLE_REFLECTION @available(*, unavailable) public struct Mirror { public enum AncestorRepresentation { case generated case customized(() -> Mirror) case suppressed } public init(reflecting subject: Any) { Builtin.unreachable() } public typealias Child = (label: String?, value: Any) public typealias Children = AnyCollection public enum DisplayStyle: Sendable { case `struct`, `class`, `enum`, tuple, optional, collection case dictionary, `set` } public init( _ subject: Subject, children: C, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) where C.Element == Child { // Can't use Builtin.unreachable() due to // https://bugs.swift.org/browse/SR-15300 self.init(reflecting: subject) } public init( _ subject: Subject, unlabeledChildren: C, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) { // Can't use Builtin.unreachable() due to // https://bugs.swift.org/browse/SR-15300 self.init(reflecting: subject) } public init( _ subject: Subject, children: KeyValuePairs, displayStyle: DisplayStyle? = nil, ancestorRepresentation: AncestorRepresentation = .generated ) { // Can't use Builtin.unreachable() due to // https://bugs.swift.org/browse/SR-15300 self.init(reflecting: subject) } public let subjectType: Any.Type public let children: Children public let displayStyle: DisplayStyle? public var superclassMirror: Mirror? { Builtin.unreachable() } } @available(*, unavailable) public protocol CustomReflectable { var customMirror: Mirror { get } } @available(*, unavailable) public protocol CustomLeafReflectable: CustomReflectable {} @available(*, unavailable) public protocol MirrorPath {} @available(*, unavailable) extension Int: MirrorPath {} @available(*, unavailable) extension String: MirrorPath {} @available(*, unavailable) extension Mirror { public func descendant(_ first: MirrorPath, _ rest: MirrorPath...) -> Any? { Builtin.unreachable() } } #endif // SWIFT_ENABLE_REFLECTION //===--- General Utilities ------------------------------------------------===// extension String { /// Creates a string representing the given value. /// /// Use this initializer to convert an instance of any type to its preferred /// representation as a `String` instance. The initializer creates the /// string representation of `instance` in one of the following ways, /// depending on its protocol conformance: /// /// - If `instance` conforms to the `TextOutputStreamable` protocol, the /// result is obtained by calling `instance.write(to: s)` on an empty /// string `s`. /// - If `instance` conforms to the `CustomStringConvertible` protocol, the /// result is `instance.description`. /// - If `instance` conforms to the `CustomDebugStringConvertible` protocol, /// the result is `instance.debugDescription`. /// - An unspecified result is supplied automatically by the Swift standard /// library. /// /// For example, this custom `Point` struct uses the default representation /// supplied by the standard library. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(describing: p)) /// // Prints "Point(x: 21, y: 30)" /// /// After adding `CustomStringConvertible` conformance by implementing the /// `description` property, `Point` provides its own custom representation. /// /// extension Point: CustomStringConvertible { /// var description: String { /// return "(\(x), \(y))" /// } /// } /// /// print(String(describing: p)) /// // Prints "(21, 30)" public init(describing instance: Subject) { self.init() _print_unlocked(instance, &self) } // These overloads serve as fast paths for init(describing:), but they // also preserve source compatibility for clients which accidentally // used init(stringInterpolationSegment:) through constructs like // myArray.map(String.init). /// Creates a string representing the given value. /// /// Use this initializer to convert an instance of any type to its preferred /// representation as a `String` instance. The initializer creates the /// string representation of `instance` in one of the following ways, /// depending on its protocol conformance: /// /// - If `instance` conforms to the `TextOutputStreamable` protocol, the /// result is obtained by calling `instance.write(to: s)` on an empty /// string `s`. /// - If `instance` conforms to the `CustomStringConvertible` protocol, the /// result is `instance.description`. /// - If `instance` conforms to the `CustomDebugStringConvertible` protocol, /// the result is `instance.debugDescription`. /// - An unspecified result is supplied automatically by the Swift standard /// library. /// /// For example, this custom `Point` struct uses the default representation /// supplied by the standard library. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(describing: p)) /// // Prints "Point(x: 21, y: 30)" /// /// After adding `CustomStringConvertible` conformance by implementing the /// `description` property, `Point` provides its own custom representation. /// /// extension Point: CustomStringConvertible { /// var description: String { /// return "(\(x), \(y))" /// } /// } /// /// print(String(describing: p)) /// // Prints "(21, 30)" @inlinable public init(describing instance: Subject) { self = instance.description } /// Creates a string representing the given value. /// /// Use this initializer to convert an instance of any type to its preferred /// representation as a `String` instance. The initializer creates the /// string representation of `instance` in one of the following ways, /// depending on its protocol conformance: /// /// - If `instance` conforms to the `TextOutputStreamable` protocol, the /// result is obtained by calling `instance.write(to: s)` on an empty /// string `s`. /// - If `instance` conforms to the `CustomStringConvertible` protocol, the /// result is `instance.description`. /// - If `instance` conforms to the `CustomDebugStringConvertible` protocol, /// the result is `instance.debugDescription`. /// - An unspecified result is supplied automatically by the Swift standard /// library. /// /// For example, this custom `Point` struct uses the default representation /// supplied by the standard library. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(describing: p)) /// // Prints "Point(x: 21, y: 30)" /// /// After adding `CustomStringConvertible` conformance by implementing the /// `description` property, `Point` provides its own custom representation. /// /// extension Point: CustomStringConvertible { /// var description: String { /// return "(\(x), \(y))" /// } /// } /// /// print(String(describing: p)) /// // Prints "(21, 30)" @inlinable public init(describing instance: Subject) { self.init() instance.write(to: &self) } /// Creates a string representing the given value. /// /// Use this initializer to convert an instance of any type to its preferred /// representation as a `String` instance. The initializer creates the /// string representation of `instance` in one of the following ways, /// depending on its protocol conformance: /// /// - If `instance` conforms to the `TextOutputStreamable` protocol, the /// result is obtained by calling `instance.write(to: s)` on an empty /// string `s`. /// - If `instance` conforms to the `CustomStringConvertible` protocol, the /// result is `instance.description`. /// - If `instance` conforms to the `CustomDebugStringConvertible` protocol, /// the result is `instance.debugDescription`. /// - An unspecified result is supplied automatically by the Swift standard /// library. /// /// For example, this custom `Point` struct uses the default representation /// supplied by the standard library. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(describing: p)) /// // Prints "Point(x: 21, y: 30)" /// /// After adding `CustomStringConvertible` conformance by implementing the /// `description` property, `Point` provides its own custom representation. /// /// extension Point: CustomStringConvertible { /// var description: String { /// return "(\(x), \(y))" /// } /// } /// /// print(String(describing: p)) /// // Prints "(21, 30)" @inlinable public init(describing instance: Subject) where Subject: CustomStringConvertible & TextOutputStreamable { self = instance.description } /// Creates a string with a detailed representation of the given value, /// suitable for debugging. /// /// Use this initializer to convert an instance of any type to its custom /// debugging representation. The initializer creates the string /// representation of `instance` in one of the following ways, depending on /// its protocol conformance: /// /// - If `subject` conforms to the `CustomDebugStringConvertible` protocol, /// the result is `subject.debugDescription`. /// - If `subject` conforms to the `CustomStringConvertible` protocol, the /// result is `subject.description`. /// - If `subject` conforms to the `TextOutputStreamable` protocol, the /// result is obtained by calling `subject.write(to: s)` on an empty /// string `s`. /// - An unspecified result is supplied automatically by the Swift standard /// library. /// /// For example, this custom `Point` struct uses the default representation /// supplied by the standard library. /// /// struct Point { /// let x: Int, y: Int /// } /// /// let p = Point(x: 21, y: 30) /// print(String(reflecting: p)) /// // Prints "p: Point = { /// // x = 21 /// // y = 30 /// // }" /// /// After adding `CustomDebugStringConvertible` conformance by implementing /// the `debugDescription` property, `Point` provides its own custom /// debugging representation. /// /// extension Point: CustomDebugStringConvertible { /// var debugDescription: String { /// return "Point(x: \(x), y: \(y))" /// } /// } /// /// print(String(reflecting: p)) /// // Prints "Point(x: 21, y: 30)" public init(reflecting subject: Subject) { self.init() _debugPrint_unlocked(subject, &self) } } #if SWIFT_ENABLE_REFLECTION /// Reflection for `Mirror` itself. extension Mirror: CustomStringConvertible { public var description: String { return "Mirror for \(self.subjectType)" } } extension Mirror: CustomReflectable { public var customMirror: Mirror { return Mirror(self, children: [:]) } } #endif // SWIFT_ENABLE_REFLECTION