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// Copyright (c) 2014, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
/// Defines the element model. The element model describes the semantic (as
/// opposed to syntactic) structure of Dart code. The syntactic structure of the
/// code is modeled by the [AST
/// structure](../dart_ast_ast/dart_ast_ast-library.html).
///
/// The element model consists of two closely related kinds of objects: elements
/// (instances of a subclass of [Element]) and types. This library defines the
/// elements, the types are defined in
/// [type.dart](../dart_element_type/dart_element_type-library.html).
///
/// Generally speaking, an element represents something that is declared in the
/// code, such as a class, method, or variable. Elements are organized in a tree
/// structure in which the children of an element are the elements that are
/// logically (and often syntactically) part of the declaration of the parent.
/// For example, the elements representing the methods and fields in a class are
/// children of the element representing the class.
///
/// Every complete element structure is rooted by an instance of the class
/// [LibraryElement]. A library element represents a single Dart library. Every
/// library is defined by one or more compilation units (the library and all of
/// its parts). The compilation units are represented by the class
/// [CompilationUnitElement] and are children of the library that is defined by
/// them. Each compilation unit can contain zero or more top-level declarations,
/// such as classes, functions, and variables. Each of these is in turn
/// represented as an element that is a child of the compilation unit. Classes
/// contain methods and fields, methods can contain local variables, etc.
///
/// The element model does not contain everything in the code, only those things
/// that are declared by the code. For example, it does not include any
/// representation of the statements in a method body, but if one of those
/// statements declares a local variable then the local variable will be
/// represented by an element.
import 'package:analyzer/dart/analysis/features.dart';
import 'package:analyzer/dart/analysis/session.dart';
import 'package:analyzer/dart/constant/value.dart';
import 'package:analyzer/dart/element/nullability_suffix.dart';
import 'package:analyzer/dart/element/scope.dart';
import 'package:analyzer/dart/element/type.dart';
import 'package:analyzer/dart/element/type_provider.dart';
import 'package:analyzer/dart/element/type_system.dart';
import 'package:analyzer/error/error.dart';
import 'package:analyzer/src/dart/constant/evaluation.dart';
import 'package:analyzer/src/dart/resolver/scope.dart' show Namespace;
import 'package:analyzer/src/generated/engine.dart' show AnalysisContext;
import 'package:analyzer/src/generated/source.dart';
import 'package:analyzer/src/generated/utilities_dart.dart';
import 'package:analyzer/src/task/api/model.dart' show AnalysisTarget;
import 'package:meta/meta.dart';
import 'package:pub_semver/pub_semver.dart';
/// A library augmentation import directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class AugmentationImportElement implements _ExistingElement {
@Deprecated('Use enclosingElement3 instead')
@override
LibraryOrAugmentationElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
LibraryOrAugmentationElement get enclosingElement2;
@override
LibraryOrAugmentationElement get enclosingElement3;
/// Returns the [LibraryAugmentationElement], if [uri] is a
/// [DirectiveUriWithAugmentation].
LibraryAugmentationElement? get importedAugmentation;
/// The offset of the `import` keyword.
int get importKeywordOffset;
/// The interpretation of the URI specified in the directive.
DirectiveUri get uri;
}
/// The result of applying augmentations to a [ClassElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class AugmentedClassElement implements AugmentedInterfaceElement {}
/// The result of applying augmentations to a [EnumElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class AugmentedEnumElement implements AugmentedInterfaceElement {}
/// The result of applying augmentations to a [InterfaceElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class AugmentedInterfaceElement {
/// Returns accessors (getters and setters) declared in this element.
///
/// [PropertyAccessorAugmentationElement]s replace corresponding elements,
/// other [PropertyAccessorElement]s are appended.
List<PropertyAccessorElement> get accessors;
/// Returns constructors declared in this element.
///
/// [ConstructorAugmentationElement]s replace corresponding elements,
/// other [ConstructorElement]s are appended.
List<ConstructorElement> get constructors;
/// Returns fields declared in this element.
///
/// [FieldAugmentationElement]s replace corresponding elements, other
/// [FieldElement]s are appended.
List<FieldElement> get fields;
/// Returns interfaces implemented by this element.
///
/// This is a union of interfaces declared by the class declaration and
/// all its augmentations.
List<InterfaceType> get interfaces;
/// Returns metadata associated with this element.
///
/// This is a union of annotations associated with the class declaration and
/// all its augmentations.
List<ElementAnnotation> get metadata;
/// Returns methods declared in this element.
///
/// [MethodAugmentationElement]s replace corresponding elements, other
/// [MethodElement]s are appended.
List<MethodElement> get methods;
/// Returns mixins applied by this class or in its augmentations.
///
/// This is a union of mixins applied by the class declaration and all its
/// augmentations.
List<InterfaceType> get mixins;
/// Returns the unnamed constructor from [constructors].
ConstructorElement? get unnamedConstructor;
/// Returns the field from [fields] that has the given [name].
FieldElement? getField(String name);
/// Returns the getter from [accessors] that has the given [name].
PropertyAccessorElement? getGetter(String name);
/// Returns the method from [methods] that has the given [name].
MethodElement? getMethod(String name);
/// Returns the constructor from [constructors] that has the given [name].
ConstructorElement? getNamedConstructor(String name);
/// Returns the setter from [accessors] that has the given [name].
PropertyAccessorElement? getSetter(String name);
}
/// The result of applying augmentations to a [MixinElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class AugmentedMixinElement extends AugmentedInterfaceElement {
/// Returns superclass constraints of this element.
///
/// This is a union of constraints declared by the class declaration and
/// all its augmentations.
List<InterfaceType> get superclassConstraints;
}
/// A class augmentation, defined by a class augmentation declaration.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class ClassAugmentationElement implements ClassOrAugmentationElement {
/// Returns the element that is augmented by this augmentation; or `null` if
/// there is no corresponding element to be augmented. The chain of
/// augmentations should normally end with a [ClassElement], but might end
/// with `null` immediately or after a few intermediate
/// [ClassAugmentationElement]s in case of invalid code when an augmentation
/// is declared without the corresponding class declaration.
ClassOrAugmentationElement? get augmentationTarget;
}
/// An element that represents a class or a mixin. The class can be defined by
/// either a class declaration (with a class body), a mixin application (without
/// a class body), a mixin declaration, or an enum declaration.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassElement
implements
ClassOrAugmentationElement,
InterfaceElement,
_TmpSharedClassElement {
/// Returns the result of applying augmentations to this class.
AugmentedClassElement get augmented;
}
/// An element that is contained within a [ClassElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassMemberElement implements Element {
// TODO(brianwilkerson) Either remove this class or rename it to something
// more correct.
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement2;
@override
Element get enclosingElement3;
/// Return `true` if this element is a static element. A static element is an
/// element that is not associated with a particular instance, but rather with
/// an entire library or class.
bool get isStatic;
}
/// Shared interface between [ClassElement] and [ClassAugmentationElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class ClassOrAugmentationElement
implements InterfaceOrAugmentationElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [ClassAugmentationElement.augmentationTarget] is the back
/// pointer that will point at this element.
ClassAugmentationElement? get augmentation;
}
/// An element representing a compilation unit.
///
/// Clients may not extend, implement or mix-in this class.
abstract class CompilationUnitElement implements UriReferencedElement {
/// Return a list containing all of the top-level accessors (getters and
/// setters) contained in this compilation unit.
List<PropertyAccessorElement> get accessors;
/// Return a list containing all of the classes contained in this compilation
/// unit.
List<ClassElement> get classes;
@Deprecated('Use enclosingElement3 instead')
@override
LibraryElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
LibraryOrAugmentationElement get enclosingElement2;
/// Return the library, or library augmentation that encloses this unit.
@override
LibraryOrAugmentationElement get enclosingElement3;
/// Return a list containing all of the enums contained in this compilation
/// unit.
@Deprecated('Use enums2 instead')
List<ClassElement> get enums;
/// Return a list containing all of the enums contained in this compilation
/// unit.
List<EnumElement> get enums2;
/// Return a list containing all of the extensions contained in this
/// compilation unit.
List<ExtensionElement> get extensions;
/// Return a list containing all of the top-level functions contained in this
/// compilation unit.
List<FunctionElement> get functions;
/// Return the [LineInfo] for the [source].
LineInfo get lineInfo;
/// Return a list containing all of the mixins contained in this compilation
/// unit.
@Deprecated('Use mixins2 instead')
List<ClassElement> get mixins;
/// Return a list containing all of the mixins contained in this compilation
/// unit.
List<MixinElement> get mixins2;
@override
AnalysisSession get session;
/// Return a list containing all of the top-level variables contained in this
/// compilation unit.
List<TopLevelVariableElement> get topLevelVariables;
/// Return a list containing all of the type aliases contained in this
/// compilation unit.
List<TypeAliasElement> get typeAliases;
/// Return the class defined in this compilation unit that has the given
/// [name], or `null` if this compilation unit does not define a class with
/// the given name.
ClassElement? getClass(String name);
/// Return the enum defined in this compilation unit that has the given
/// [name], or `null` if this compilation unit does not define an enum with
/// the given name.
@Deprecated('Use getEnum2() instead')
ClassElement? getEnum(String name);
/// Return the enum defined in this compilation unit that has the given
/// [name], or `null` if this compilation unit does not define an enum with
/// the given name.
EnumElement? getEnum2(String name);
/// Return the class defined in this compilation unit that has the given
/// [name], or `null` if this compilation unit does not define a class with
/// the given name.
@Deprecated('Use getClass() instead')
ClassElement? getType(String name);
}
/// An element representing a constructor augmentation.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorAugmentationElement implements ConstructorElement {
/// Returns the element that is augmented by this augmentation. The chain of
/// augmentations should normally end with a [ConstructorElement] that is not
/// [ConstructorAugmentationElement], but might end with `null` immediately
/// or after a few intermediate [ConstructorAugmentationElement]s in case of
/// invalid code when an augmentation is declared without the corresponding
/// constructor declaration.
ConstructorElement? get augmentationTarget;
}
/// An element representing a constructor or a factory method defined within a
/// class.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorElement
implements ClassMemberElement, ExecutableElement, ConstantEvaluationTarget {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [ConstructorAugmentationElement.augmentationTarget] is
/// the back pointer that will point at this element.
ConstructorAugmentationElement? get augmentation;
@override
ConstructorElement get declaration;
@override
String get displayName;
@Deprecated('Use enclosingElement3 instead')
@override
ClassElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
ClassElement get enclosingElement2;
@override
InterfaceElement get enclosingElement3;
/// Return `true` if this constructor is a const constructor.
bool get isConst;
/// Return `true` if this constructor can be used as a default constructor -
/// unnamed and has no required parameters.
bool get isDefaultConstructor;
/// Return `true` if this constructor represents a factory constructor.
bool get isFactory;
/// Return `true` if this constructor represents a generative constructor.
bool get isGenerative;
@override
String get name;
/// Return the offset of the character immediately following the last
/// character of this constructor's name, or `null` if not named.
///
/// TODO(migration): encapsulate [nameEnd] and [periodOffset]?
int? get nameEnd;
/// Return the offset of the `.` before this constructor name, or `null` if
/// not named.
int? get periodOffset;
/// Return the constructor to which this constructor is redirecting, or `null`
/// if this constructor does not redirect to another constructor or if the
/// library containing this constructor has not yet been resolved.
ConstructorElement? get redirectedConstructor;
@override
InterfaceType get returnType;
}
/// [ImportElementPrefix] that is used together with `deferred`.
///
/// Clients may not extend, implement or mix-in this class.
abstract class DeferredImportElementPrefix implements ImportElementPrefix {}
/// Meaning of a URI referenced in a directive.
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUri {}
/// [DirectiveUriWithSource] that references a [LibraryAugmentationElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithAugmentation extends DirectiveUriWithSource {
/// The library augmentation referenced by the [source].
LibraryAugmentationElement get augmentation;
}
/// [DirectiveUriWithSource] that references a [LibraryElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithLibrary extends DirectiveUriWithSource {
/// The library referenced by the [source].
LibraryElement get library;
}
/// [DirectiveUriWithRelativeUriString] that can be parsed into a relative URI.
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithRelativeUri
extends DirectiveUriWithRelativeUriString {
/// The relative URI, parsed from [relativeUriString].
Uri get relativeUri;
}
/// [DirectiveUri] for which we can get its relative URI string.
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithRelativeUriString extends DirectiveUri {
/// The relative URI string specified in code.
String get relativeUriString;
}
/// [DirectiveUriWithRelativeUri] that resolves to a [Source].
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithSource extends DirectiveUriWithRelativeUri {
/// The result of resolving [relativeUri] against the enclosing URI.
Source get source;
}
/// [DirectiveUriWithSource] that references a [CompilationUnitElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class DirectiveUriWithUnit extends DirectiveUriWithSource {
/// The unit referenced by the [source].
CompilationUnitElement get unit;
}
/// The base class for all of the elements in the element model. Generally
/// speaking, the element model is a semantic model of the program that
/// represents things that are declared with a name and hence can be referenced
/// elsewhere in the code.
///
/// There are two exceptions to the general case. First, there are elements in
/// the element model that are created for the convenience of various kinds of
/// analysis but that do not have any corresponding declaration within the
/// source code. Such elements are marked as being <i>synthetic</i>. Examples of
/// synthetic elements include
/// * default constructors in classes that do not define any explicit
/// constructors,
/// * getters and setters that are induced by explicit field declarations,
/// * fields that are induced by explicit declarations of getters and setters,
/// and
/// * functions representing the initialization expression for a variable.
///
/// Second, there are elements in the element model that do not have a name.
/// These correspond to unnamed functions and exist in order to more accurately
/// represent the semantic structure of the program.
///
/// Clients may not extend, implement or mix-in this class.
abstract class Element implements AnalysisTarget {
/// Return the analysis context in which this element is defined.
AnalysisContext get context;
/// Return the declaration of this element. If the element is a view on an
/// element, e.g. a method from an interface type, with substituted type
/// parameters, return the corresponding element from the class, without any
/// substitutions. If this element is already a declaration (or a synthetic
/// element, e.g. a synthetic property accessor), return itself.
Element? get declaration;
/// Return the display name of this element, possibly the empty string if
/// this element does not have a name.
///
/// In most cases the name and the display name are the same. Differences
/// though are cases such as setters where the name of some setter `set f(x)`
/// is `f=`, instead of `f`.
String get displayName;
/// Return the content of the documentation comment (including delimiters) for
/// this element, or `null` if this element does not or cannot have
/// documentation.
String? get documentationComment;
/// Return the element that either physically or logically encloses this
/// element. This will be `null` if this element is a library because
/// libraries are the top-level elements in the model.
@Deprecated('Use enclosingElement3 instead')
Element? get enclosingElement;
/// Return the element that either physically or logically encloses this
/// element. This will be `null` if this element is a library because
/// libraries are the top-level elements in the model.
@Deprecated('Use enclosingElement3 instead')
Element? get enclosingElement2;
/// Return the element that either physically or logically encloses this
/// element. This will be `null` if this element is a library because
/// libraries are the top-level elements in the model.
Element? get enclosingElement3;
/// Return `true` if this element has an annotation of the form
/// `@alwaysThrows`.
bool get hasAlwaysThrows;
/// Return `true` if this element has an annotation of the form `@deprecated`
/// or `@Deprecated('..')`.
bool get hasDeprecated;
/// Return `true` if this element has an annotation of the form `@doNotStore`.
bool get hasDoNotStore;
/// Return `true` if this element has an annotation of the form `@factory`.
bool get hasFactory;
/// Return `true` if this element has an annotation of the form `@internal`.
bool get hasInternal;
/// Return `true` if this element has an annotation of the form `@isTest`.
bool get hasIsTest;
/// Return `true` if this element has an annotation of the form
/// `@isTestGroup`.
bool get hasIsTestGroup;
/// Return `true` if this element has an annotation of the form `@JS(..)`.
bool get hasJS;
/// Return `true` if this element has an annotation of the form `@literal`.
bool get hasLiteral;
/// Return `true` if this element has an annotation of the form
/// `@mustBeOverridden`.
bool get hasMustBeOverridden;
/// Return `true` if this element has an annotation of the form
/// `@mustCallSuper`.
bool get hasMustCallSuper;
/// Return `true` if this element has an annotation of the form `@nonVirtual`.
bool get hasNonVirtual;
/// Return `true` if this element has an annotation of the form
/// `@optionalTypeArgs`.
bool get hasOptionalTypeArgs;
/// Return `true` if this element has an annotation of the form `@override`.
bool get hasOverride;
/// Return `true` if this element has an annotation of the form `@protected`.
bool get hasProtected;
/// Return `true` if this element has an annotation of the form `@required`.
bool get hasRequired;
/// Return `true` if this element has an annotation of the form `@sealed`.
bool get hasSealed;
/// Return `true` if this element has an annotation of the form `@useResult`
/// or `@UseResult('..')`.
bool get hasUseResult;
/// Return `true` if this element has an annotation of the form
/// `@visibleForOverriding`.
bool get hasVisibleForOverriding;
/// Return `true` if this element has an annotation of the form
/// `@visibleForTemplate`.
bool get hasVisibleForTemplate;
/// Return `true` if this element has an annotation of the form
/// `@visibleForTesting`.
bool get hasVisibleForTesting;
/// The unique integer identifier of this element.
int get id;
/// Return `true` if this element is private. Private elements are visible
/// only within the library in which they are declared.
bool get isPrivate;
/// Return `true` if this element is public. Public elements are visible
/// within any library that imports the library in which they are declared.
bool get isPublic;
/// Return `true` if this element is synthetic. A synthetic element is an
/// element that is not represented in the source code explicitly, but is
/// implied by the source code, such as the default constructor for a class
/// that does not explicitly define any constructors.
bool get isSynthetic;
/// Return the kind of element that this is.
ElementKind get kind;
/// Return the library that contains this element. This will be the element
/// itself if it is a library element. This will be `null` if this element is
/// [MultiplyDefinedElement] that is not contained in a library.
LibraryElement? get library;
/// Return an object representing the location of this element in the element
/// model. The object can be used to locate this element at a later time.
ElementLocation? get location;
/// Return a list containing all of the metadata associated with this element.
/// The array will be empty if the element does not have any metadata or if
/// the library containing this element has not yet been resolved.
List<ElementAnnotation> get metadata;
/// Return the name of this element, or `null` if this element does not have a
/// name.
String? get name;
/// Return the length of the name of this element in the file that contains
/// the declaration of this element, or `0` if this element does not have a
/// name.
int get nameLength;
/// Return the offset of the name of this element in the file that contains
/// the declaration of this element, or `-1` if this element is synthetic,
/// does not have a name, or otherwise does not have an offset.
int get nameOffset;
/// Return the non-synthetic element that caused this element to be created.
///
/// If this element is not synthetic, then the element itself is returned.
///
/// If this element is synthetic, then the corresponding non-synthetic
/// element is returned. For example, for a synthetic getter of a
/// non-synthetic field the field is returned; for a synthetic constructor
/// the enclosing class is returned.
Element get nonSynthetic;
/// Return the analysis session in which this element is defined.
AnalysisSession? get session;
@override
Source? get source;
/// Use the given [visitor] to visit this element. Return the value returned
/// by the visitor as a result of visiting this element.
T? accept<T>(ElementVisitor<T> visitor);
/// Return the presentation of this element as it should appear when
/// presented to users.
///
/// If [withNullability] is `true`, then [NullabilitySuffix.question] and
/// [NullabilitySuffix.star] in types will be represented as `?` and `*`.
/// [NullabilitySuffix.none] does not have any explicit presentation.
///
/// If [withNullability] is `false`, nullability suffixes will not be
/// included into the presentation.
///
/// If [multiline] is `true`, the string may be wrapped over multiple lines
/// with newlines to improve formatting. For example function signatures may
/// be formatted as if they had trailing commas.
///
/// Clients should not depend on the content of the returned value as it will
/// be changed if doing so would improve the UX.
String getDisplayString({
required bool withNullability,
bool multiline = false,
});
/// Return a display name for the given element that includes the path to the
/// compilation unit in which the type is defined. If [shortName] is `null`
/// then [displayName] will be used as the name of this element. Otherwise
/// the provided name will be used.
// TODO(brianwilkerson) Make the parameter optional.
String getExtendedDisplayName(String? shortName);
/// Return `true` if this element, assuming that it is within scope, is
/// accessible to code in the given [library]. This is defined by the Dart
/// Language Specification in section 3.2:
/// <blockquote>
/// A declaration <i>m</i> is accessible to library <i>L</i> if <i>m</i> is
/// declared in <i>L</i> or if <i>m</i> is public.
/// </blockquote>
@Deprecated('Use isAccessibleIn2() instead')
bool isAccessibleIn(LibraryElement? library);
/// Return `true` if this element, assuming that it is within scope, is
/// accessible to code in the given [library]. This is defined by the Dart
/// Language Specification in section 6.2:
/// <blockquote>
/// A declaration <i>m</i> is accessible to a library <i>L</i> if <i>m</i> is
/// declared in <i>L</i> or if <i>m</i> is public.
/// </blockquote>
bool isAccessibleIn2(LibraryElement library);
/// Return either this element or the most immediate ancestor of this element
/// for which the [predicate] returns `true`, or `null` if there is no such
/// element.
E? thisOrAncestorMatching<E extends Element>(
bool Function(Element) predicate,
);
/// Return either this element or the most immediate ancestor of this element
/// that has the given type, or `null` if there is no such element.
E? thisOrAncestorOfType<E extends Element>();
/// Use the given [visitor] to visit all of the children of this element.
/// There is no guarantee of the order in which the children will be visited.
void visitChildren(ElementVisitor visitor);
}
/// A single annotation associated with an element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ElementAnnotation implements ConstantEvaluationTarget {
/// Return the errors that were produced while computing a value for this
/// annotation, or `null` if no value has been computed. If a value has been
/// produced but no errors were generated, then the list will be empty.
List<AnalysisError>? get constantEvaluationErrors;
/// Return the element referenced by this annotation.
///
/// In valid code this element can be a [PropertyAccessorElement] getter
/// of a constant top-level variable, or a constant static field of a
/// class; or a constant [ConstructorElement].
///
/// In invalid code this element can be `null`, or a reference to any
/// other element.
Element? get element;
/// Return `true` if this annotation marks the associated function as always
/// throwing.
bool get isAlwaysThrows;
/// Return `true` if this annotation marks the associated element as being
/// deprecated.
bool get isDeprecated;
/// Return `true` if this annotation marks the associated element as not to be
/// stored.
bool get isDoNotStore;
/// Return `true` if this annotation marks the associated member as a factory.
bool get isFactory;
/// Return `true` if this annotation marks the associated class and its
/// subclasses as being immutable.
bool get isImmutable;
/// Return `true` if this annotation marks the associated element as being
/// internal to its package.
bool get isInternal;
/// Return `true` if this annotation marks the associated member as running
/// a single test.
bool get isIsTest;
/// Return `true` if this annotation marks the associated member as running
/// a test group.
bool get isIsTestGroup;
/// Return `true` if this annotation marks the associated element with the
/// `JS` annotation.
bool get isJS;
/// Return `true` if this annotation marks the associated constructor as
/// being literal.
bool get isLiteral;
/// Return `true` if this annotation marks the associated member as requiring
/// subclasses to override this member.
bool get isMustBeOverridden;
/// Return `true` if this annotation marks the associated member as requiring
/// overriding methods to call super.
bool get isMustCallSuper;
/// Return `true` if this annotation marks the associated member as being
/// non-virtual.
bool get isNonVirtual;
/// Return `true` if this annotation marks the associated type as
/// having "optional" type arguments.
bool get isOptionalTypeArgs;
/// Return `true` if this annotation marks the associated method as being
/// expected to override an inherited method.
bool get isOverride;
/// Return `true` if this annotation marks the associated member as being
/// protected.
bool get isProtected;
/// Return `true` if this annotation marks the associated class as
/// implementing a proxy object.
bool get isProxy;
/// Return `true` if this annotation marks the associated member as being
/// required.
bool get isRequired;
/// Return `true` if this annotation marks the associated class as being
/// sealed.
bool get isSealed;
/// Return `true` if this annotation marks the associated class as being
/// intended to be used as an annotation.
bool get isTarget;
/// Return `true` if this annotation marks the associated returned element as
/// requiring use.
bool get isUseResult;
/// Return `true` if this annotation marks the associated member as being
/// visible for overriding only.
bool get isVisibleForOverriding;
/// Return `true` if this annotation marks the associated member as being
/// visible for template files.
bool get isVisibleForTemplate;
/// Return `true` if this annotation marks the associated member as being
/// visible for testing.
bool get isVisibleForTesting;
/// Return a representation of the value of this annotation, forcing the value
/// to be computed if it had not previously been computed, or `null` if the
/// value of this annotation could not be computed because of errors.
DartObject? computeConstantValue();
/// Return a textual description of this annotation in a form approximating
/// valid source. The returned string will not be valid source primarily in
/// the case where the annotation itself is not well-formed.
String toSource();
}
/// The kind of elements in the element model.
///
/// Clients may not extend, implement or mix-in this class.
class ElementKind implements Comparable<ElementKind> {
static const ElementKind AUGMENTATION_IMPORT =
ElementKind('AUGMENTATION_IMPORT', 0, "augmentation import");
static const ElementKind CLASS = ElementKind('CLASS', 1, "class");
static const ElementKind COMPILATION_UNIT =
ElementKind('COMPILATION_UNIT', 2, "compilation unit");
static const ElementKind CONSTRUCTOR =
ElementKind('CONSTRUCTOR', 3, "constructor");
static const ElementKind DYNAMIC = ElementKind('DYNAMIC', 4, "<dynamic>");
static const ElementKind ENUM = ElementKind('ENUM', 5, "enum");
static const ElementKind ERROR = ElementKind('ERROR', 6, "<error>");
static const ElementKind EXPORT =
ElementKind('EXPORT', 7, "export directive");
static const ElementKind EXTENSION = ElementKind('EXTENSION', 8, "extension");
static const ElementKind FIELD = ElementKind('FIELD', 9, "field");
static const ElementKind FUNCTION = ElementKind('FUNCTION', 10, "function");
static const ElementKind GENERIC_FUNCTION_TYPE =
ElementKind('GENERIC_FUNCTION_TYPE', 11, 'generic function type');
static const ElementKind GETTER = ElementKind('GETTER', 12, "getter");
static const ElementKind IMPORT =
ElementKind('IMPORT', 13, "import directive");
static const ElementKind LABEL = ElementKind('LABEL', 14, "label");
static const ElementKind LIBRARY = ElementKind('LIBRARY', 15, "library");
static const ElementKind LIBRARY_AUGMENTATION =
ElementKind('LIBRARY_AUGMENTATION', 16, "library augmentation");
static const ElementKind LOCAL_VARIABLE =
ElementKind('LOCAL_VARIABLE', 17, "local variable");
static const ElementKind METHOD = ElementKind('METHOD', 18, "method");
static const ElementKind NAME = ElementKind('NAME', 19, "<name>");
static const ElementKind NEVER = ElementKind('NEVER', 20, "<never>");
static const ElementKind PARAMETER =
ElementKind('PARAMETER', 21, "parameter");
static const ElementKind PART = ElementKind('PART', 22, "part");
static const ElementKind PREFIX = ElementKind('PREFIX', 23, "import prefix");
static const ElementKind RECORD = ElementKind('RECORD', 24, "record");
static const ElementKind SETTER = ElementKind('SETTER', 25, "setter");
static const ElementKind TOP_LEVEL_VARIABLE =
ElementKind('TOP_LEVEL_VARIABLE', 26, "top level variable");
static const ElementKind FUNCTION_TYPE_ALIAS =
ElementKind('FUNCTION_TYPE_ALIAS', 27, "function type alias");
static const ElementKind TYPE_PARAMETER =
ElementKind('TYPE_PARAMETER', 28, "type parameter");
static const ElementKind TYPE_ALIAS =
ElementKind('TYPE_ALIAS', 29, "type alias");
static const ElementKind UNIVERSE = ElementKind('UNIVERSE', 30, "<universe>");
static const List<ElementKind> values = [
CLASS,
COMPILATION_UNIT,
CONSTRUCTOR,
DYNAMIC,
ENUM,
ERROR,
EXPORT,
FIELD,
FUNCTION,
GENERIC_FUNCTION_TYPE,
GETTER,
IMPORT,
LABEL,
LIBRARY,
LOCAL_VARIABLE,
METHOD,
NAME,
NEVER,
PARAMETER,
PART,
PREFIX,
RECORD,
SETTER,
TOP_LEVEL_VARIABLE,
FUNCTION_TYPE_ALIAS,
TYPE_PARAMETER,
UNIVERSE
];
/// The name of this element kind.
final String name;
/// The ordinal value of the element kind.
final int ordinal;
/// The name displayed in the UI for this kind of element.
final String displayName;
/// Initialize a newly created element kind to have the given [displayName].
const ElementKind(this.name, this.ordinal, this.displayName);
@override
int get hashCode => ordinal;
@override
int compareTo(ElementKind other) => ordinal - other.ordinal;
@override
String toString() => name;
/// Return the kind of the given [element], or [ERROR] if the element is
/// `null`. This is a utility method that can reduce the need for null checks
/// in other places.
static ElementKind of(Element? element) {
if (element == null) {
return ERROR;
}
return element.kind;
}
}
/// The location of an element within the element model.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ElementLocation {
/// Return the path to the element whose location is represented by this
/// object. Clients must not modify the returned array.
List<String> get components;
/// Return an encoded representation of this location that can be used to
/// create a location that is equal to this location.
String get encoding;
}
/// An object that can be used to visit an element structure.
///
/// Clients may not extend, implement or mix-in this class. There are classes
/// that implement this interface that provide useful default behaviors in
/// `package:analyzer/dart/element/visitor.dart`. A couple of the most useful
/// include
/// * SimpleElementVisitor which implements every visit method by doing nothing,
/// * RecursiveElementVisitor which will cause every node in a structure to be
/// visited, and
/// * ThrowingElementVisitor which implements every visit method by throwing an
/// exception.
abstract class ElementVisitor<R> {
R? visitAugmentationImportElement(AugmentationImportElement element);
R? visitClassElement(ClassElement element);
R? visitCompilationUnitElement(CompilationUnitElement element);
R? visitConstructorElement(ConstructorElement element);
R? visitEnumElement(EnumElement element);
@Deprecated('Override visitLibraryExportElement() instead')
R? visitExportElement(ExportElement element);
R? visitExtensionElement(ExtensionElement element);
R? visitFieldElement(FieldElement element);
R? visitFieldFormalParameterElement(FieldFormalParameterElement element);
R? visitFunctionElement(FunctionElement element);
R? visitGenericFunctionTypeElement(GenericFunctionTypeElement element);
@Deprecated('Override visitLibraryImportElement() instead')
R? visitImportElement(ImportElement element);
R? visitLabelElement(LabelElement element);
R? visitLibraryAugmentationElement(LibraryAugmentationElement element);
R? visitLibraryElement(LibraryElement element);
R? visitLibraryExportElement(LibraryExportElement element);
R? visitLibraryImportElement(LibraryImportElement element);
R? visitLocalVariableElement(LocalVariableElement element);
R? visitMethodElement(MethodElement element);
R? visitMixinElement(MixinElement element);
R? visitMultiplyDefinedElement(MultiplyDefinedElement element);
R? visitParameterElement(ParameterElement element);
R? visitPartElement(PartElement element);
R? visitPrefixElement(PrefixElement element);
R? visitPropertyAccessorElement(PropertyAccessorElement element);
R? visitSuperFormalParameterElement(SuperFormalParameterElement element);
R? visitTopLevelVariableElement(TopLevelVariableElement element);
R? visitTypeAliasElement(TypeAliasElement element);
R? visitTypeParameterElement(TypeParameterElement element);
}
/// An enum augmentation, defined by a enum augmentation declaration.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class EnumAugmentationElement implements EnumOrAugmentationElement {
/// Returns the element that is augmented by this augmentation; or `null` if
/// there is no corresponding element to be augmented. The chain of
/// augmentations should normally end with a [EnumElement], but might end
/// with `null` immediately or after a few intermediate
/// [EnumAugmentationElement]s in case of invalid code when an augmentation
/// is declared without the corresponding enum declaration.
EnumOrAugmentationElement? get augmentationTarget;
}
/// An element that represents an enum.
///
/// Clients may not extend, implement or mix-in this class.
abstract class EnumElement
implements
EnumOrAugmentationElement,
InterfaceElement,
_TmpSharedClassElement {
/// Returns the result of applying augmentations to this element.
AugmentedEnumElement get augmented;
}
/// Shared interface between [EnumElement] and [EnumAugmentationElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class EnumOrAugmentationElement
implements InterfaceOrAugmentationElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [EnumAugmentationElement.augmentationTarget] is the back
/// pointer that will point at this element.
EnumAugmentationElement? get augmentation;
}
/// An element representing an executable object, including functions, methods,
/// constructors, getters, and setters.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExecutableElement implements FunctionTypedElement {
@override
ExecutableElement get declaration;
@override
String get displayName;
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement2;
@override
Element get enclosingElement3;
/// Return `true` if this executable element did not have an explicit return
/// type specified for it in the original source.
bool get hasImplicitReturnType;
/// Return `true` if this executable element is abstract. Executable elements
/// are abstract if they are not external and have no body.
bool get isAbstract;
/// Return `true` if this executable element has body marked as being
/// asynchronous.
bool get isAsynchronous;
/// Return `true` if this executable element is external. Executable elements
/// are external if they are explicitly marked as such using the 'external'
/// keyword.
bool get isExternal;
/// Return `true` if this executable element has a body marked as being a
/// generator.
bool get isGenerator;
/// Return `true` if this executable element is an operator. The test may be
/// based on the name of the executable element, in which case the result will
/// be correct when the name is legal.
bool get isOperator;
/// Return `true` if this element is a static element. A static element is an
/// element that is not associated with a particular instance, but rather with
/// an entire library or class.
bool get isStatic;
/// Return `true` if this executable element has a body marked as being
/// synchronous.
bool get isSynchronous;
@override
String get name;
}
/// An export directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
@Deprecated('Use LibraryExportElement instead')
abstract class ExportElement implements UriReferencedElement {
/// Return a list containing the combinators that were specified as part of
/// the export directive in the order in which they were specified.
List<NamespaceCombinator> get combinators;
/// Return the library that is exported from this library by this export
/// directive, or `null` if the URI has invalid syntax or cannot be resolved.
LibraryElement? get exportedLibrary;
}
/// An element that represents an extension.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExtensionElement implements TypeParameterizedElement {
/// Return a list containing all of the accessors (getters and setters)
/// declared in this extension.
List<PropertyAccessorElement> get accessors;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement2;
@override
CompilationUnitElement get enclosingElement3;
/// Return the type that is extended by this extension.
DartType get extendedType;
/// Return a list containing all of the fields declared in this extension.
List<FieldElement> get fields;
/// Return a list containing all of the methods declared in this extension.
List<MethodElement> get methods;
/// Return the element representing the field with the given [name] that is
/// declared in this extension, or `null` if this extension does not declare a
/// field with the given name.
FieldElement? getField(String name);
/// Return the element representing the getter with the given [name] that is
/// declared in this extension, or `null` if this extension does not declare a
/// getter with the given name.
PropertyAccessorElement? getGetter(String name);
/// Return the element representing the method with the given [name] that is
/// declared in this extension, or `null` if this extension does not declare a
/// method with the given name.
MethodElement? getMethod(String name);
/// Return the element representing the setter with the given [name] that is
/// declared in this extension, or `null` if this extension does not declare a
/// setter with the given name.
PropertyAccessorElement? getSetter(String name);
}
/// A field augmentation defined within a class.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FieldAugmentationElement implements FieldElement {
/// Returns the element that is augmented by this augmentation. The chain of
/// augmentations should normally end with a [FieldElement] that is not
/// [FieldAugmentationElement], but might end with `null` immediately or
/// after a few intermediate [FieldAugmentationElement]s in case of invalid
/// code when an augmentation is declared without the corresponding field
/// declaration.
FieldElement? get augmentationTarget;
}
/// A field defined within a class.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FieldElement
implements ClassMemberElement, PropertyInducingElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [FieldAugmentationElement.augmentationTarget] is the
/// back pointer that will point at this element.
FieldAugmentationElement? get augmentation;
@override
FieldElement get declaration;
/// Return `true` if this field is abstract. Executable fields are abstract if
/// they are declared with the `abstract` keyword.
bool get isAbstract;
/// Return `true` if this field was explicitly marked as being covariant.
bool get isCovariant;
/// Return `true` if this element is an enum constant.
bool get isEnumConstant;
/// Return `true` if this field was explicitly marked as being external.
bool get isExternal;
/// Return `true` if this element is a static element. A static element is an
/// element that is not associated with a particular instance, but rather with
/// an entire library or class.
@override
bool get isStatic;
}
/// A field formal parameter defined within a constructor element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FieldFormalParameterElement implements ParameterElement {
/// Return the field element associated with this field formal parameter, or
/// `null` if the parameter references a field that doesn't exist.
FieldElement? get field;
}
/// A (non-method) function. This can be either a top-level function, a local
/// function, a closure, or the initialization expression for a field or
/// variable.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionElement implements ExecutableElement, LocalElement {
/// The name of the method that can be implemented by a class to allow its
/// instances to be invoked as if they were a function.
static final String CALL_METHOD_NAME = "call";
/// The name of the synthetic function defined for libraries that are
/// deferred.
static final String LOAD_LIBRARY_NAME = "loadLibrary";
/// The name of the function used as an entry point.
static const String MAIN_FUNCTION_NAME = "main";
/// The name of the method that will be invoked if an attempt is made to
/// invoke an undefined method on an object.
static final String NO_SUCH_METHOD_METHOD_NAME = "noSuchMethod";
/// Return `true` if this function represents `identical` from the
/// `dart:core` library.
bool get isDartCoreIdentical;
/// Return `true` if the function is an entry point, i.e. a top-level function
/// and has the name `main`.
bool get isEntryPoint;
}
/// An element that has a [FunctionType] as its [type].
///
/// This also provides convenient access to the parameters and return type.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionTypedElement implements TypeParameterizedElement {
/// Return a list containing all of the parameters defined by this executable
/// element.
List<ParameterElement> get parameters;
/// Return the return type defined by this element.
DartType get returnType;
/// Return the type defined by this element.
FunctionType get type;
}
/// The pseudo-declaration that defines a generic function type.
///
/// Clients may not extend, implement, or mix-in this class.
abstract class GenericFunctionTypeElement implements FunctionTypedElement {}
/// A combinator that causes some of the names in a namespace to be hidden when
/// being imported.
///
/// Clients may not extend, implement or mix-in this class.
abstract class HideElementCombinator implements NamespaceCombinator {
/// Return a list containing the names that are not to be made visible in the
/// importing library even if they are defined in the imported library.
List<String> get hiddenNames;
}
/// A single import directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
@Deprecated('Use LibraryImportElement instead')
abstract class ImportElement implements UriReferencedElement {
/// Return a list containing the combinators that were specified as part of
/// the import directive in the order in which they were specified.
List<NamespaceCombinator> get combinators;
/// Return the library that is imported into this library by this import
/// directive, or `null` if the URI has invalid syntax or cannot be resolved.
LibraryElement? get importedLibrary;
/// Return `true` if this import is for a deferred library.
bool get isDeferred;
/// The [Namespace] that this directive contributes to the containing library.
Namespace get namespace;
/// Return the prefix that was specified as part of the import directive, or
/// `null` if there was no prefix specified.
PrefixElement? get prefix;
}
/// Usage of a [PrefixElement] in an `import` directive.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ImportElementPrefix {
/// Return the prefix that was specified as part of the import directive, or
/// `null` if there was no prefix specified.
PrefixElement get element;
}
/// An element that defines an [InterfaceType].
///
/// Clients may not extend, implement or mix-in this class.
abstract class InterfaceElement
implements InterfaceOrAugmentationElement, TypeDefiningElement {
/// Return a list containing all the supertypes defined for this element and
/// its supertypes. This includes superclasses, mixins, interfaces, and
/// superclass constraints.
List<InterfaceType> get allSupertypes;
/// Return the superclass of this element.
///
/// For [ClassElement] returns `null` only if this class is `Object`. If the
/// superclass is not explicitly specified, or the superclass cannot be
/// resolved, then the implicit superclass `Object` is returned.
///
/// For [EnumElement] returns `Enum` from `dart:core`.
///
/// For [MixinElement] always returns `null`.
///
/// <b>Note:</b> Because the element model represents the state of the code,
/// it is possible for it to be semantically invalid. In particular, it is not
/// safe to assume that the inheritance structure of a class does not contain
/// a cycle. Clients that traverse the inheritance structure must explicitly
/// guard against infinite loops.
InterfaceType? get supertype;
/// Return the type of `this` expression for this element.
///
/// For a class like `class MyClass<T, U> {}` the returned type is equivalent
/// to the type `MyClass<T, U>`. So, the type arguments are the types of the
/// type parameters, and either `none` or `star` is used for the nullability
/// suffix is used, depending on the nullability status of the declaring
/// library.
InterfaceType get thisType;
/// Returns the unnamed constructor declared directly in this class. If the
/// class does not declare any constructors, a synthetic default constructor
/// will be returned.
/// TODO(scheglov) Deprecate and remove it.
ConstructorElement? get unnamedConstructor;
/// Returns the field (synthetic or explicit) defined directly in this
/// class or augmentation that has the given [name].
/// TODO(scheglov) Deprecate and remove it.
FieldElement? getField(String name);
/// Returns the getter (synthetic or explicit) defined directly in this
/// class or augmentation that has the given [name].
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? getGetter(String name);
/// Returns the method defined directly in this class or augmentation that
/// has the given [name].
/// TODO(scheglov) Deprecate and remove it.
MethodElement? getMethod(String name);
/// Returns the constructor defined directly in this class or augmentation
/// that has the given [name].
/// TODO(scheglov) Deprecate and remove it.
ConstructorElement? getNamedConstructor(String name);
/// Returns the setter (synthetic or explicit) defined directly in this
/// class or augmentation that has the given [name].
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? getSetter(String name);
/// Create the [InterfaceType] for this element with the given [typeArguments]
/// and [nullabilitySuffix].
InterfaceType instantiate({
required List<DartType> typeArguments,
required NullabilitySuffix nullabilitySuffix,
});
/// Return the element representing the method that results from looking up
/// the given [methodName] in this class with respect to the given [library],
/// ignoring abstract methods, or `null` if the look up fails. The behavior of
/// this method is defined by the Dart Language Specification in section
/// 16.15.1:
/// <blockquote>
/// The result of looking up method <i>m</i> in class <i>C</i> with respect to
/// library <i>L</i> is: If <i>C</i> declares an instance method named
/// <i>m</i> that is accessible to <i>L</i>, then that method is the result of
/// the lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the
/// result of the lookup is the result of looking up method <i>m</i> in
/// <i>S</i> with respect to <i>L</i>. Otherwise, we say that the lookup has
/// failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
MethodElement? lookUpConcreteMethod(
String methodName, LibraryElement library);
/// Return the element representing the getter that results from looking up
/// the given [getterName] in this class with respect to the given [library],
/// or `null` if the look up fails. The behavior of this method is defined by
/// the Dart Language Specification in section 16.15.2:
/// <blockquote>
/// The result of looking up getter (respectively setter) <i>m</i> in class
/// <i>C</i> with respect to library <i>L</i> is: If <i>C</i> declares an
/// instance getter (respectively setter) named <i>m</i> that is accessible to
/// <i>L</i>, then that getter (respectively setter) is the result of the
/// lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the result
/// of the lookup is the result of looking up getter (respectively setter)
/// <i>m</i> in <i>S</i> with respect to <i>L</i>. Otherwise, we say that the
/// lookup has failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? lookUpGetter(
String getterName, LibraryElement library);
/// Return the element representing the method that results from looking up
/// the given [methodName] in the superclass of this class with respect to the
/// given [library], or `null` if the look up fails. The behavior of this
/// method is defined by the Dart Language Specification in section 16.15.1:
/// <blockquote>
/// The result of looking up method <i>m</i> in class <i>C</i> with respect to
/// library <i>L</i> is: If <i>C</i> declares an instance method named
/// <i>m</i> that is accessible to <i>L</i>, then that method is the result of
/// the lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the
/// result of the lookup is the result of looking up method <i>m</i> in
/// <i>S</i> with respect to <i>L</i>. Otherwise, we say that the lookup has
/// failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
MethodElement? lookUpInheritedMethod(
String methodName, LibraryElement library);
/// Return the element representing the method that results from looking up
/// the given [methodName] in this class with respect to the given [library],
/// or `null` if the look up fails. The behavior of this method is defined by
/// the Dart Language Specification in section 16.15.1:
/// <blockquote>
/// The result of looking up method <i>m</i> in class <i>C</i> with respect to
/// library <i>L</i> is: If <i>C</i> declares an instance method named
/// <i>m</i> that is accessible to <i>L</i>, then that method is the result of
/// the lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the
/// result of the lookup is the result of looking up method <i>m</i> in
/// <i>S</i> with respect to <i>L</i>. Otherwise, we say that the lookup has
/// failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
MethodElement? lookUpMethod(String methodName, LibraryElement library);
/// Return the element representing the setter that results from looking up
/// the given [setterName] in this class with respect to the given [library],
/// or `null` if the look up fails. The behavior of this method is defined by
/// the Dart Language Specification in section 16.15.2:
/// <blockquote>
/// The result of looking up getter (respectively setter) <i>m</i> in class
/// <i>C</i> with respect to library <i>L</i> is: If <i>C</i> declares an
/// instance getter (respectively setter) named <i>m</i> that is accessible to
/// <i>L</i>, then that getter (respectively setter) is the result of the
/// lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the result
/// of the lookup is the result of looking up getter (respectively setter)
/// <i>m</i> in <i>S</i> with respect to <i>L</i>. Otherwise, we say that the
/// lookup has failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? lookUpSetter(
String setterName, LibraryElement library);
}
/// Shared interface between [InterfaceElement] and augmentations.
///
/// Augmentations of [InterfaceElement] don't have their own type,
/// so they cannot by instantiated into an [InterfaceType].
///
/// Clients may not extend, implement or mix-in this class.
abstract class InterfaceOrAugmentationElement
implements TypeParameterizedElement {
/// Return a list containing all of the accessors (getters and setters)
/// declared in this class.
List<PropertyAccessorElement> get accessors;
/// Return a list containing all of the constructors declared in this class.
/// The list will be empty if there are no constructors defined for this
/// class, as is the case when this element represents an enum or a mixin.
List<ConstructorElement> get constructors;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement2;
@override
CompilationUnitElement get enclosingElement3;
/// Return a list containing all of the fields declared in this class.
List<FieldElement> get fields;
/// Return a list containing all of the interfaces that are implemented by
/// this class.
///
/// <b>Note:</b> Because the element model represents the state of the code,
/// it is possible for it to be semantically invalid. In particular, it is not
/// safe to assume that the inheritance structure of a class does not contain
/// a cycle. Clients that traverse the inheritance structure must explicitly
/// guard against infinite loops.
List<InterfaceType> get interfaces;
/// Return a list containing all of the methods declared in this class.
List<MethodElement> get methods;
/// Return a list containing all of the mixins that are applied to the class
/// being extended in order to derive the superclass of this class.
///
/// [ClassElement] and [EnumElement] can have mixins.
///
/// [MixinElement] cannot have mixins, so the empty list is returned.
///
/// <b>Note:</b> Because the element model represents the state of the code,
/// it is possible for it to be semantically invalid. In particular, it is not
/// safe to assume that the inheritance structure of a class does not contain
/// a cycle. Clients that traverse the inheritance structure must explicitly
/// guard against infinite loops.
List<InterfaceType> get mixins;
@override
String get name;
}
/// A label associated with a statement.
///
/// Clients may not extend, implement or mix-in this class.
abstract class LabelElement implements Element {
@Deprecated('Use enclosingElement3 instead')
@override
ExecutableElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
ExecutableElement get enclosingElement2;
@override
ExecutableElement get enclosingElement3;
@override
String get name;
}
/// A library augmentation.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class LibraryAugmentationElement
implements LibraryOrAugmentationElement, _ExistingElement {
/// Returns the library that is augmented by this augmentation.
LibraryOrAugmentationElement get augmentationTarget;
}
/// A library.
///
/// Clients may not extend, implement or mix-in this class.
abstract class LibraryElement
implements LibraryOrAugmentationElement, _ExistingElement {
/// Return the entry point for this library, or `null` if this library does
/// not have an entry point. The entry point is defined to be a zero argument
/// top-level function whose name is `main`.
FunctionElement? get entryPoint;
/// Return a list containing all of the libraries that are exported from this
/// library.
List<LibraryElement> get exportedLibraries;
/// The export [Namespace] of this library.
Namespace get exportNamespace;
/// Return an identifier that uniquely identifies this element among the
/// children of this element's parent.
String get identifier;
/// Return a list containing all of the libraries that are imported into this
/// library. This includes all of the libraries that are imported using a
/// prefix and those that are imported without a prefix.
List<LibraryElement> get importedLibraries;
/// Return `true` if this library is an application that can be run in the
/// browser.
bool get isBrowserApplication;
/// Return `true` if this library is the dart:async library.
bool get isDartAsync;
/// Return `true` if this library is the dart:core library.
bool get isDartCore;
/// Return `true` if this library is part of the SDK.
bool get isInSdk;
/// Return the element representing the synthetic function `loadLibrary` that
/// is implicitly defined for this library if the library is imported using a
/// deferred import.
FunctionElement get loadLibraryFunction;
/// Return the name of this library, possibly the empty string if this
/// library does not have an explicit name.
@override
String get name;
/// Return a list containing all of the compilation units that are included in
/// this library using a `part` directive. This does not include the defining
/// compilation unit that contains the `part` directives.
@Deprecated('Use parts2 instead')
List<CompilationUnitElement> get parts;
/// Returns the list of `part` directives of this library.
List<PartElement> get parts2;
/// The public [Namespace] of this library.
Namespace get publicNamespace;
/// Return the top-level elements defined in each of the compilation units
/// that are included in this library. This includes both public and private
/// elements, but does not include imports, exports, or synthetic elements.
Iterable<Element> get topLevelElements;
/// Return a list containing all of the compilation units this library
/// consists of. This includes the defining compilation unit and units
/// included using the `part` directive.
List<CompilationUnitElement> get units;
/// Return the class defined in this library that has the given [name], or
/// `null` if this library does not define a class with the given name.
ClassElement? getClass(String name);
/// Return a list containing all of the imports that share the given [prefix],
/// or an empty array if there are no such imports.
@Deprecated('Use PrefixElement.imports instead')
List<ImportElement> getImportsWithPrefix(PrefixElement prefix);
/// Return the class defined in this library that has the given [name], or
/// `null` if this library does not define a class with the given name.
@Deprecated('Use getClass() instead')
ClassElement? getType(String className);
/// If a legacy library, return the legacy view on the [element].
/// Otherwise, return the original element.
T toLegacyElementIfOptOut<T extends Element>(T element);
/// If a legacy library, return the legacy version of the [type].
/// Otherwise, return the original type.
DartType toLegacyTypeIfOptOut(DartType type);
}
/// A single export directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
abstract class LibraryExportElement implements _ExistingElement {
/// Return a list containing the combinators that were specified as part of
/// the export directive in the order in which they were specified.
List<NamespaceCombinator> get combinators;
/// Returns the [LibraryElement], if [uri] is a [DirectiveUriWithLibrary].
LibraryElement? get exportedLibrary;
/// The offset of the `export` keyword.
int get exportKeywordOffset;
/// The interpretation of the URI specified in the directive.
DirectiveUri get uri;
}
/// A single import directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
abstract class LibraryImportElement implements _ExistingElement {
/// Return a list containing the combinators that were specified as part of
/// the import directive in the order in which they were specified.
List<NamespaceCombinator> get combinators;
/// Returns the [LibraryElement], if [uri] is a [DirectiveUriWithLibrary].
LibraryElement? get importedLibrary;
/// The offset of the `import` keyword.
int get importKeywordOffset;
/// The [Namespace] that this directive contributes to the containing library.
Namespace get namespace;
/// Return the prefix that was specified as part of the import directive, or
/// `null` if there was no prefix specified.
ImportElementPrefix? get prefix;
/// The interpretation of the URI specified in the directive.
DirectiveUri get uri;
}
class LibraryLanguageVersion {
/// The version for the whole package that contains this library.
final Version package;
/// The version specified using `@dart` override, `null` if absent or invalid.
final Version? override;
LibraryLanguageVersion({
required this.package,
required this.override,
});
/// The effective language version for the library.
Version get effective {
return override ?? package;
}
}
/// Shared interface between [LibraryElement] and [LibraryAugmentationElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class LibraryOrAugmentationElement implements Element {
/// Returns a list containing all of the extension elements accessible within
/// this library.
List<ExtensionElement> get accessibleExtensions;
/// Returns the augmentation imports specified in this library.
@experimental
List<AugmentationImportElement> get augmentationImports;
/// Return the compilation unit that defines this library.
CompilationUnitElement get definingCompilationUnit;
/// Return a list containing all of the exports defined in this library.
@Deprecated('Use libraryExports instead')
List<ExportElement> get exports;
/// The set of features available to this library.
///
/// Determined by the combination of the language version for the enclosing
/// package, enabled experiments, and the presence of a `// @dart` language
/// version override comment at the top of the file.
FeatureSet get featureSet;
/// Return a list containing all of the imports defined in this library.
@Deprecated('Use libraryImports instead')
List<ImportElement> get imports;
bool get isNonNullableByDefault;
/// The language version for this library.
LibraryLanguageVersion get languageVersion;
@override
LibraryElement get library;
/// Return a list containing all of the exports defined in this library.
List<LibraryExportElement> get libraryExports;
/// Return a list containing all of the imports defined in this library.
List<LibraryImportElement> get libraryImports;
/// Return a list containing elements for each of the prefixes used to
/// `import` libraries into this library. Each prefix can be used in more
/// than one `import` directive.
List<PrefixElement> get prefixes;
/// Return the name lookup scope for this library. It consists of elements
/// that are either declared in the library, or imported into it.
Scope get scope;
@override
AnalysisSession get session;
/// Return the [TypeProvider] that is used in this library.
TypeProvider get typeProvider;
/// Return the [TypeSystem] that is used in this library.
TypeSystem get typeSystem;
}
/// An element that can be (but is not required to be) defined within a method
/// or function (an [ExecutableElement]).
///
/// Clients may not extend, implement or mix-in this class.
abstract class LocalElement implements Element {}
/// A local variable.
///
/// Clients may not extend, implement or mix-in this class.
abstract class LocalVariableElement implements PromotableElement {
/// Return `true` if this variable has an initializer at declaration.
bool get hasInitializer;
@override
String get name;
}
/// An element that represents a method augmentation defined within a class.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MethodAugmentationElement implements MethodElement {
/// Returns the element that is augmented by this augmentation. The chain of
/// augmentations should normally end with a [MethodElement] that is not
/// [MethodAugmentationElement], but might end with `null` immediately or
/// after a few intermediate [MethodAugmentationElement]s in case of invalid
/// code when an augmentation is declared without the corresponding method
/// declaration.
MethodElement? get augmentationTarget;
}
/// An element that represents a method defined within a class.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MethodElement implements ClassMemberElement, ExecutableElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [MethodAugmentationElement.augmentationTarget] is the
/// back pointer that will point at this element.
MethodAugmentationElement? get augmentation;
@override
MethodElement get declaration;
}
/// A class augmentation, defined by a mixin augmentation declaration.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class MixinAugmentationElement implements MixinOrAugmentationElement {
/// Returns the element that is augmented by this augmentation; or `null` if
/// there is no corresponding element to be augmented. The chain of
/// augmentations should normally end with a [MixinElement], but might end
/// with `null` immediately or after a few intermediate
/// [MixinAugmentationElement]s in case of invalid code when an augmentation
/// is declared without the corresponding class declaration.
MixinOrAugmentationElement? get augmentationTarget;
}
/// An element that represents a mixin.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MixinElement
implements
MixinOrAugmentationElement,
InterfaceElement,
_TmpSharedClassElement {
/// Returns the result of applying augmentations to this element.
AugmentedMixinElement get augmented;
/// Returns the superclass constraints defined for this mixin. If the
/// declaration does not have an `on` clause, then the list will contain
/// the type for the class `Object`.
///
/// <b>Note:</b> Because the element model represents the state of the code,
/// it is possible for it to be semantically invalid. In particular, it is not
/// safe to assume that the inheritance structure of a class does not contain
/// a cycle. Clients that traverse the inheritance structure must explicitly
/// guard against infinite loops.
@override
List<InterfaceType> get superclassConstraints;
}
/// Shared interface between [MixinElement] and [MixinAugmentationElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class MixinOrAugmentationElement
implements InterfaceOrAugmentationElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [MixinAugmentationElement.augmentationTarget] is the back
/// pointer that will point at this element.
MixinAugmentationElement? get augmentation;
}
/// A pseudo-element that represents multiple elements defined within a single
/// scope that have the same name. This situation is not allowed by the
/// language, so objects implementing this interface always represent an error.
/// As a result, most of the normal operations on elements do not make sense
/// and will return useless results.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MultiplyDefinedElement implements Element {
/// Return a list containing all of the elements that were defined within the
/// scope to have the same name.
List<Element> get conflictingElements;
}
/// An [ExecutableElement], with the additional information of a list of
/// [ExecutableElement]s from which this element was composed.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MultiplyInheritedExecutableElement implements ExecutableElement {
/// Return a list containing all of the executable elements defined within
/// this executable element.
List<ExecutableElement> get inheritedElements;
}
/// An object that controls how namespaces are combined.
///
/// Clients may not extend, implement or mix-in this class.
abstract class NamespaceCombinator {}
/// A parameter defined within an executable element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ParameterElement
implements PromotableElement, ConstantEvaluationTarget {
@override
ParameterElement get declaration;
/// Return the Dart code of the default value, or `null` if no default value.
String? get defaultValueCode;
/// Return `true` if this parameter has a default value.
bool get hasDefaultValue;
/// Return `true` if this parameter is covariant, meaning it is allowed to
/// have a narrower type in an override.
bool get isCovariant;
/// Return `true` if this parameter is an initializing formal parameter.
bool get isInitializingFormal;
/// Return `true` if this parameter is a named parameter. Named parameters
/// that are annotated with the `@required` annotation are considered
/// optional. Named parameters that are annotated with the `required` syntax
/// are considered required.
bool get isNamed;
/// Return `true` if this parameter is a required parameter. Required
/// parameters are always positional, unless the experiment 'non-nullable' is
/// enabled, in which case named parameters can also be required.
///
/// Note: regardless of the state of the 'non-nullable' experiment, the
/// presence or absence of the `@required` annotation does not change the
/// meaning of this getter. The parameter `{@required int x}` will return
/// `false` and the parameter `{@required required int x}` will return
/// `true`
@Deprecated('Use isRequired instead')
bool get isNotOptional;
/// Return `true` if this parameter is an optional parameter. Optional
/// parameters can either be positional or named. Named parameters that are
/// annotated with the `@required` annotation are considered optional. Named
/// parameters that are annotated with the `required` syntax are considered
/// required.
bool get isOptional;
/// Return `true` if this parameter is both an optional and named parameter.
/// Named parameters that are annotated with the `@required` annotation are
/// considered optional. Named parameters that are annotated with the
/// `required` syntax are considered required.
bool get isOptionalNamed;
/// Return `true` if this parameter is both an optional and positional
/// parameter.
bool get isOptionalPositional;
/// Return `true` if this parameter is a positional parameter. Positional
/// parameters can either be required or optional.
bool get isPositional;
/// Return `true` if this parameter is either a required positional
/// parameter, or a named parameter with the `required` keyword.
///
/// Note: the presence or absence of the `@required` annotation does not
/// change the meaning of this getter. The parameter `{@required int x}`
/// will return `false` and the parameter `{@required required int x}`
/// will return `true`.
bool get isRequired;
/// Return `true` if this parameter is both a required and named parameter.
/// Named parameters that are annotated with the `@required` annotation are
/// considered optional. Named parameters that are annotated with the
/// `required` syntax are considered required.
bool get isRequiredNamed;
/// Return `true` if this parameter is both a required and positional
/// parameter.
bool get isRequiredPositional;
/// Return `true` if this parameter is a super formal parameter.
bool get isSuperFormal;
@override
String get name;
/// Return the kind of this parameter.
@Deprecated('Use the getters isOptionalNamed, isOptionalPositional, '
'isRequiredNamed, and isRequiredPositional')
ParameterKind get parameterKind;
/// Return a list containing all of the parameters defined by this parameter.
/// A parameter will only define other parameters if it is a function typed
/// parameter.
List<ParameterElement> get parameters;
/// Return a list containing all of the type parameters defined by this
/// parameter. A parameter will only define other parameters if it is a
/// function typed parameter.
List<TypeParameterElement> get typeParameters;
/// Append the type, name and possibly the default value of this parameter to
/// the given [buffer].
void appendToWithoutDelimiters(
StringBuffer buffer, {
bool withNullability = false,
});
}
/// A 'part' directive within a library.
///
/// Clients may not extend, implement or mix-in this class.
abstract class PartElement implements _ExistingElement {
/// The interpretation of the URI specified in the directive.
DirectiveUri get uri;
}
/// A prefix used to import one or more libraries into another library.
///
/// Clients may not extend, implement or mix-in this class.
abstract class PrefixElement implements _ExistingElement {
@Deprecated('Use enclosingElement3 instead')
@override
LibraryElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
LibraryOrAugmentationElement get enclosingElement2;
/// Return the library, or library augmentation that encloses this element.
@override
LibraryOrAugmentationElement get enclosingElement3;
/// Return the imports that share this prefix.
@Deprecated('Use imports2 instead')
List<ImportElement> get imports;
/// Return the imports that share this prefix.
List<LibraryImportElement> get imports2;
@override
String get name;
/// Return the name lookup scope for this import prefix. It consists of
/// elements imported into the enclosing library with this prefix. The
/// namespace combinators of the import directives are taken into account.
Scope get scope;
}
/// A variable that might be subject to type promotion. This might be a local
/// variable or a parameter.
///
/// Clients may not extend, implement or mix-in this class.
abstract class PromotableElement implements LocalElement, VariableElement {
// Promotable elements are guaranteed to have a name.
@override
String get name;
}
/// Augmentation of a [PropertyAccessorElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class PropertyAccessorAugmentationElement
implements PropertyAccessorElement {
/// Returns the element that is augmented by this augmentation. The chain of
/// augmentations should normally end with a [PropertyAccessorElement] that
/// is not [PropertyAccessorAugmentationElement], but might end with `null`
/// immediately or after a few intermediate
/// [PropertyAccessorAugmentationElement]s in case of invalid code when an
/// augmentation is declared without the corresponding property accessor
/// declaration.
PropertyAccessorElement? get augmentationTarget;
}
/// A getter or a setter. Note that explicitly defined property accessors
/// implicitly define a synthetic field. Symmetrically, synthetic accessors are
/// implicitly created for explicitly defined fields. The following rules apply:
///
/// * Every explicit field is represented by a non-synthetic [FieldElement].
/// * Every explicit field induces a getter and possibly a setter, both of which
/// are represented by synthetic [PropertyAccessorElement]s.
/// * Every explicit getter or setter is represented by a non-synthetic
/// [PropertyAccessorElement].
/// * Every explicit getter or setter (or pair thereof if they have the same
/// name) induces a field that is represented by a synthetic [FieldElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class PropertyAccessorElement implements ExecutableElement {
/// The immediate augmentation of this element, or `null` if there are no
/// augmentations. [PropertyAccessorAugmentationElement.augmentationTarget]
/// is the back pointer that will point at this element.
PropertyAccessorAugmentationElement? get augmentation;
/// Return the accessor representing the getter that corresponds to (has the
/// same name as) this setter, or `null` if this accessor is not a setter or
/// if there is no corresponding getter.
PropertyAccessorElement? get correspondingGetter;
/// Return the accessor representing the setter that corresponds to (has the
/// same name as) this getter, or `null` if this accessor is not a getter or
/// if there is no corresponding setter.
PropertyAccessorElement? get correspondingSetter;
@override
PropertyAccessorElement get declaration;
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
Element get enclosingElement2;
@override
Element get enclosingElement3;
/// Return `true` if this accessor represents a getter.
bool get isGetter;
/// Return `true` if this accessor represents a setter.
bool get isSetter;
/// Return the field or top-level variable associated with this accessor. If
/// this accessor was explicitly defined (is not synthetic) then the variable
/// associated with it will be synthetic.
PropertyInducingElement get variable;
}
/// A variable that has an associated getter and possibly a setter. Note that
/// explicitly defined variables implicitly define a synthetic getter and that
/// non-`final` explicitly defined variables implicitly define a synthetic
/// setter. Symmetrically, synthetic fields are implicitly created for
/// explicitly defined getters and setters. The following rules apply:
///
/// * Every explicit variable is represented by a non-synthetic
/// [PropertyInducingElement].
/// * Every explicit variable induces a getter and possibly a setter, both of
/// which are represented by synthetic [PropertyAccessorElement]s.
/// * Every explicit getter or setter is represented by a non-synthetic
/// [PropertyAccessorElement].
/// * Every explicit getter or setter (or pair thereof if they have the same
/// name) induces a variable that is represented by a synthetic
/// [PropertyInducingElement].
///
/// Clients may not extend, implement or mix-in this class.
abstract class PropertyInducingElement implements VariableElement {
@override
String get displayName;
/// Return the getter associated with this variable. If this variable was
/// explicitly defined (is not synthetic) then the getter associated with it
/// will be synthetic.
PropertyAccessorElement? get getter;
/// Return `true` if this variable has an initializer at declaration.
bool get hasInitializer;
@override
LibraryElement get library;
@override
String get name;
/// Return the setter associated with this variable, or `null` if the variable
/// is effectively `final` and therefore does not have a setter associated
/// with it. (This can happen either because the variable is explicitly
/// defined as being `final` or because the variable is induced by an
/// explicit getter that does not have a corresponding setter.) If this
/// variable was explicitly defined (is not synthetic) then the setter
/// associated with it will be synthetic.
PropertyAccessorElement? get setter;
}
/// A record shape, declared or synthesized. There might be multiple
/// declarations of the same record shape in the code under analysis, even in
/// the same file. A record shape can be synthesized from two or more other
/// record shapes, e.g. with `a ?? b`.
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class RecordElement implements _ExistingElement {
/// The named fields (might be empty).
List<RecordNamedFieldElement> get namedFields;
/// The positional fields (might be empty).
List<RecordPositionalFieldElement> get positionalFields;
/// Returns [RecordType] with [nullabilitySuffix] and declared field types.
RecordType instantiate({
required NullabilitySuffix nullabilitySuffix,
});
}
/// A field in a [RecordElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class RecordFieldElement implements _ExistingElement {
@override
RecordElement get enclosingElement3;
/// The type of the field.
DartType get type;
}
/// A named field in a [RecordElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class RecordNamedFieldElement implements RecordFieldElement {
/// The name of the field.
@override
String get name;
}
/// A positional field in a [RecordElement].
///
/// Clients may not extend, implement or mix-in this class.
@experimental
abstract class RecordPositionalFieldElement implements RecordFieldElement {}
/// A combinator that cause some of the names in a namespace to be visible (and
/// the rest hidden) when being imported.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ShowElementCombinator implements NamespaceCombinator {
/// Return the offset of the character immediately following the last
/// character of this node.
int get end;
/// Return the offset of the 'show' keyword of this element.
int get offset;
/// Return a list containing the names that are to be made visible in the
/// importing library if they are defined in the imported library.
List<String> get shownNames;
}
/// A super formal parameter defined within a constructor element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class SuperFormalParameterElement implements ParameterElement {
/// The associated super-constructor parameter, from the super-constructor
/// that is referenced by the implicit or explicit super-constructor
/// invocation.
///
/// Can be `null` for erroneous code - not existing super-constructor,
/// no corresponding parameter in the super-constructor.
ParameterElement? get superConstructorParameter;
}
/// A top-level variable.
///
/// Clients may not extend, implement or mix-in this class.
abstract class TopLevelVariableElement implements PropertyInducingElement {
@override
TopLevelVariableElement get declaration;
/// Return `true` if this field was explicitly marked as being external.
bool get isExternal;
}
/// A type alias (`typedef`).
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeAliasElement
implements TypeParameterizedElement, TypeDefiningElement {
/// If the aliased type has structure, return the corresponding element.
/// For example it could be [GenericFunctionTypeElement].
///
/// If there is no structure, return `null`.
Element? get aliasedElement;
/// Return the aliased type.
///
/// If non-function type aliases feature is enabled for the enclosing library,
/// this type might be just anything. If the feature is disabled, return
/// a [FunctionType].
DartType get aliasedType;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement;
@Deprecated('Use enclosingElement3 instead')
@override
CompilationUnitElement get enclosingElement2;
@override
CompilationUnitElement get enclosingElement3;
@override
String get name;
/// Produces the type resulting from instantiating this typedef with the given
/// [typeArguments] and [nullabilitySuffix].
///
/// Note that this always instantiates the typedef itself, so for a
/// [TypeAliasElement] the returned [DartType] might still be a generic
/// type, with type formals. For example, if the typedef is:
/// typedef F<T> = void Function<U>(T, U);
/// then `F<int>` will produce `void Function<U>(int, U)`.
DartType instantiate({
required List<DartType> typeArguments,
required NullabilitySuffix nullabilitySuffix,
});
}
/// An element that defines a type.
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeDefiningElement implements Element {}
/// A type parameter.
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeParameterElement implements TypeDefiningElement {
/// Return the type representing the bound associated with this parameter, or
/// `null` if this parameter does not have an explicit bound. Being able to
/// distinguish between an implicit and explicit bound is needed by the
/// instantiate to bounds algorithm.
DartType? get bound;
@override
TypeParameterElement get declaration;
@override
String get displayName;
@override
String get name;
/// Create the [TypeParameterType] with the given [nullabilitySuffix] for
/// this type parameter.
TypeParameterType instantiate({
required NullabilitySuffix nullabilitySuffix,
});
}
/// An element that has type parameters, such as a class or a typedef. This also
/// includes functions and methods if support for generic methods is enabled.
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeParameterizedElement implements _ExistingElement {
/// If the element defines a type, indicates whether the type may safely
/// appear without explicit type parameters as the bounds of a type parameter
/// declaration.
///
/// If the element does not define a type, returns `true`.
bool get isSimplyBounded;
/// Return a list containing all of the type parameters declared by this
/// element directly. This does not include type parameters that are declared
/// by any enclosing elements.
List<TypeParameterElement> get typeParameters;
}
/// A pseudo-elements that represents names that are undefined. This situation
/// is not allowed by the language, so objects implementing this interface
/// always represent an error. As a result, most of the normal operations on
/// elements do not make sense and will return useless results.
///
/// Clients may not extend, implement or mix-in this class.
abstract class UndefinedElement implements Element {}
/// An element included into a library using some URI.
///
/// Clients may not extend, implement or mix-in this class.
abstract class UriReferencedElement implements _ExistingElement {
/// Return the URI that is used to include this element into the enclosing
/// library, or `null` if this is the defining compilation unit of a library.
String? get uri;
/// Return the offset of the character immediately following the last
/// character of this node's URI, or `-1` for synthetic import.
int get uriEnd;
/// Return the offset of the URI in the file, or `-1` if this element is
/// synthetic.
int get uriOffset;
}
/// A variable. There are more specific subclasses for more specific kinds of
/// variables.
///
/// Clients may not extend, implement or mix-in this class.
abstract class VariableElement implements Element, ConstantEvaluationTarget {
@override
VariableElement get declaration;
/// Return `true` if this variable element did not have an explicit type
/// specified for it.
bool get hasImplicitType;
/// Return `true` if this variable was declared with the 'const' modifier.
bool get isConst;
/// Return `true` if this variable was declared with the 'final' modifier.
/// Variables that are declared with the 'const' modifier will return `false`
/// even though they are implicitly final.
bool get isFinal;
/// Return `true` if this variable uses late evaluation semantics.
///
/// This will always return `false` unless the experiment 'non-nullable' is
/// enabled.
bool get isLate;
/// Return `true` if this element is a static variable, as per section 8 of
/// the Dart Language Specification:
///
/// > A static variable is a variable that is not associated with a particular
/// > instance, but rather with an entire library or class. Static variables
/// > include library variables and class variables. Class variables are
/// > variables whose declaration is immediately nested inside a class
/// > declaration and includes the modifier static. A library variable is
/// > implicitly static.
bool get isStatic;
@override
String get name;
/// Return the declared type of this variable.
DartType get type;
/// Return a representation of the value of this variable, forcing the value
/// to be computed if it had not previously been computed, or `null` if either
/// this variable was not declared with the 'const' modifier or if the value
/// of this variable could not be computed because of errors.
DartObject? computeConstantValue();
}
/// This class exists to provide non-nullable overrides for existing elements,
/// as opposite to artificial "multiply defined" element.
abstract class _ExistingElement implements Element {
@override
Element get declaration;
@override
LibraryElement get library;
@override
Source get librarySource;
@override
Source get source;
}
/// Properties that existed in [ClassElement], so we should keep them for
/// backward compatibility for now. But we want them to be either moved, or
/// removed.
abstract class _TmpSharedClassElement {
/// Return `true` if this class or its superclass declares a non-final
/// instance field.
bool get hasNonFinalField;
/// Return `true` if this class declares a static member.
@Deprecated('Not useful for clients')
bool get hasStaticMember;
/// Return `true` if this class is abstract. A class is abstract if it has an
/// explicit `abstract` modifier or if it is implicitly abstract, such as a
/// class defined by a mixin declaration. Note, that this definition of
/// <i>abstract</i> is different from <i>has unimplemented members</i>.
/// TODO(scheglov) Deprecate and replace it.
bool get isAbstract;
/// Return `true` if this class represents the class 'Enum' defined in the
/// dart:core library.
bool get isDartCoreEnum;
/// Return `true` if this class represents the class 'Object' defined in the
/// dart:core library.
bool get isDartCoreObject;
/// Return `true` if this class is defined by an enum declaration.
@Deprecated('Use `is EnumElement` instead')
bool get isEnum;
/// Return `true` if this class is defined by a mixin declaration.
@Deprecated('Use `is MixinElement` instead')
bool get isMixin;
/// Return `true` if this class is a mixin application. A class is a mixin
/// application if it was declared using the syntax "class A = B with C;".
bool get isMixinApplication;
/// Return `true` if this class can validly be used as a mixin when defining
/// another class. For classes defined by a mixin declaration, the result is
/// always `true`. For classes defined by a class declaration or a mixin
/// application, the behavior of this method is defined by the Dart Language
/// Specification in section 9:
/// <blockquote>
/// It is a compile-time error if a declared or derived mixin refers to super.
/// It is a compile-time error if a declared or derived mixin explicitly
/// declares a constructor. It is a compile-time error if a mixin is derived
/// from a class whose superclass is not Object.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
bool get isValidMixin;
/// Return a list containing all of the superclass constraints defined for
/// this class. The list will be empty if this class does not represent a
/// mixin declaration. If this class _does_ represent a mixin declaration but
/// the declaration does not have an `on` clause, then the list will contain
/// the type for the class `Object`.
///
/// <b>Note:</b> Because the element model represents the state of the code,
/// it is possible for it to be semantically invalid. In particular, it is not
/// safe to assume that the inheritance structure of a class does not contain
/// a cycle. Clients that traverse the inheritance structure must explicitly
/// guard against infinite loops.
/// TODO(scheglov) Deprecate and remove it.
List<InterfaceType> get superclassConstraints;
/// Return the element representing the getter that results from looking up
/// the given [getterName] in the superclass of this class with respect to the
/// given [library], ignoring abstract getters, or `null` if the look up
/// fails. The behavior of this method is defined by the Dart Language
/// Specification in section 16.15.2:
/// <blockquote>
/// The result of looking up getter (respectively setter) <i>m</i> in class
/// <i>C</i> with respect to library <i>L</i> is: If <i>C</i> declares an
/// instance getter (respectively setter) named <i>m</i> that is accessible to
/// <i>L</i>, then that getter (respectively setter) is the result of the
/// lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the result
/// of the lookup is the result of looking up getter (respectively setter)
/// <i>m</i> in <i>S</i> with respect to <i>L</i>. Otherwise, we say that the
/// lookup has failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? lookUpInheritedConcreteGetter(
String getterName, LibraryElement library);
/// Return the element representing the method that results from looking up
/// the given [methodName] in the superclass of this class with respect to the
/// given [library], ignoring abstract methods, or `null` if the look up
/// fails. The behavior of this method is defined by the Dart Language
/// Specification in section 16.15.1:
/// <blockquote>
/// The result of looking up method <i>m</i> in class <i>C</i> with respect to
/// library <i>L</i> is: If <i>C</i> declares an instance method named
/// <i>m</i> that is accessible to <i>L</i>, then that method is the result of
/// the lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the
/// result of the lookup is the result of looking up method <i>m</i> in
/// <i>S</i> with respect to <i>L</i>. Otherwise, we say that the lookup has
/// failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
MethodElement? lookUpInheritedConcreteMethod(
String methodName, LibraryElement library);
/// Return the element representing the setter that results from looking up
/// the given [setterName] in the superclass of this class with respect to the
/// given [library], ignoring abstract setters, or `null` if the look up
/// fails. The behavior of this method is defined by the Dart Language
/// Specification in section 16.15.2:
/// <blockquote>
/// The result of looking up getter (respectively setter) <i>m</i> in class
/// <i>C</i> with respect to library <i>L</i> is: If <i>C</i> declares an
/// instance getter (respectively setter) named <i>m</i> that is accessible to
/// <i>L</i>, then that getter (respectively setter) is the result of the
/// lookup. Otherwise, if <i>C</i> has a superclass <i>S</i>, then the result
/// of the lookup is the result of looking up getter (respectively setter)
/// <i>m</i> in <i>S</i> with respect to <i>L</i>. Otherwise, we say that the
/// lookup has failed.
/// </blockquote>
/// TODO(scheglov) Deprecate and remove it.
PropertyAccessorElement? lookUpInheritedConcreteSetter(
String setterName, LibraryElement library);
}