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dart / sdk.git / 588609d60c270efd9cf981372445c641e142b4fd / . / pkg / analyzer / lib / dart / ast / ast.dart
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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 AST model. The AST (Abstract Syntax Tree) model describes the
/// syntactic (as opposed to semantic) structure of Dart code. The semantic
/// structure of the code is modeled by the
/// [element model](../dart_element_element/dart_element_element-library.html).
///
/// An AST consists of nodes (instances of a subclass of [AstNode]). The nodes
/// are organized in a tree structure in which the children of a node are the
/// smaller syntactic units from which the node is composed. For example, a
/// binary expression consists of two sub-expressions (the operands) and an
/// operator. The two expressions are represented as nodes. The operator is not
/// represented as a node.
///
/// The AST is constructed by the parser based on the sequence of tokens
/// produced by the scanner. Most nodes provide direct access to the tokens used
/// to build the node. For example, the token for the operator in a binary
/// expression can be accessed from the node representing the binary expression.
///
/// While any node can theoretically be the root of an AST structure, almost all
/// of the AST structures known to the analyzer have a [CompilationUnit] as the
/// root of the structure. A compilation unit represents all of the Dart code in
/// a single file.
///
/// An AST can be either unresolved or resolved. When an AST is unresolved
/// certain properties will not have been computed and the accessors for those
/// properties will return `null`. The documentation for those getters should
/// describe that this is a possibility.
///
/// When an AST is resolved, the identifiers in the AST will be associated with
/// the elements that they refer to and every expression in the AST will have a
/// type associated with it.
import 'package:analyzer/dart/analysis/features.dart';
import 'package:analyzer/dart/ast/precedence.dart';
import 'package:analyzer/dart/ast/syntactic_entity.dart';
import 'package:analyzer/dart/ast/token.dart';
import 'package:analyzer/dart/element/element.dart';
import 'package:analyzer/dart/element/type.dart';
import 'package:analyzer/src/generated/java_engine.dart';
import 'package:analyzer/src/generated/source.dart' show LineInfo, Source;
/// Two or more string literals that are implicitly concatenated because of
/// being adjacent (separated only by whitespace).
///
/// While the grammar only allows adjacent strings when all of the strings are
/// of the same kind (single line or multi-line), this class doesn't enforce
/// that restriction.
///
/// adjacentStrings ::=
/// [StringLiteral] [StringLiteral]+
///
/// Clients may not extend, implement or mix-in this class.
abstract class AdjacentStrings implements StringLiteral {
/// Return the strings that are implicitly concatenated.
NodeList<StringLiteral> get strings;
}
/// An AST node that can be annotated with both a documentation comment and a
/// list of annotations.
///
/// Clients may not extend, implement or mix-in this class.
abstract class AnnotatedNode implements AstNode {
/// Return the documentation comment associated with this node, or `null` if
/// this node does not have a documentation comment associated with it.
Comment? get documentationComment;
/// Return the first token following the comment and metadata.
Token get firstTokenAfterCommentAndMetadata;
/// Return the annotations associated with this node.
NodeList<Annotation> get metadata;
/// Return a list containing the comment and annotations associated with this
/// node, sorted in lexical order.
List<AstNode> get sortedCommentAndAnnotations;
}
/// An annotation that can be associated with an AST node.
///
/// metadata ::=
/// annotation*
///
/// annotation ::=
/// '@' metadatum
///
/// metadatum ::=
/// [Identifier]
/// | qualifiedName
/// | constructorDesignation argumentPart
///
/// Clients may not extend, implement or mix-in this class.
abstract class Annotation implements AstNode {
/// Return the arguments to the constructor being invoked, or `null` if this
/// annotation is not the invocation of a constructor.
ArgumentList? get arguments;
/// Return the at sign that introduced the annotation.
Token get atSign;
/// Return the name of the constructor being invoked, or `null` if this
/// annotation is not the invocation of a named constructor.
SimpleIdentifier? get constructorName;
/// Return the element associated with this annotation, or `null` if the AST
/// structure has not been resolved or if this annotation could not be
/// resolved.
Element? get element;
/// Return the element annotation representing this annotation in the element
/// model; `null` when the AST has not been resolved.
ElementAnnotation? get elementAnnotation;
/// Return the name of the class defining the constructor that is being
/// invoked or the name of the field that is being referenced.
Identifier get name;
@override
AstNode get parent;
/// Return the period before the constructor name, or `null` if this
/// annotation is not the invocation of a named constructor.
Token? get period;
/// Returns the type arguments to the constructor being invoked, or `null` if
/// (a) this annotation is not the invocation of a constructor or (b) this
/// annotation does not specify type arguments explicitly.
///
/// Note that type arguments are only valid if [Feature.generic_metadata] is
/// enabled.
TypeArgumentList? get typeArguments;
}
/// A list of arguments in the invocation of an executable element (that is, a
/// function, method, or constructor).
///
/// argumentList ::=
/// '(' arguments? ')'
///
/// arguments ::=
/// [NamedExpression] (',' [NamedExpression])*
/// | [Expression] (',' [Expression])* (',' [NamedExpression])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class ArgumentList implements AstNode {
/// Return the expressions producing the values of the arguments.
///
/// Although the language requires that positional arguments appear before
/// named arguments, this class allows them to be intermixed.
NodeList<Expression> get arguments;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// An as expression.
///
/// asExpression ::=
/// [Expression] 'as' [TypeAnnotation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class AsExpression implements Expression {
/// Return the 'as' operator.
Token get asOperator;
/// Return the expression used to compute the value being cast.
Expression get expression;
/// Return the type being cast to.
TypeAnnotation get type;
}
/// An assert in the initializer list of a constructor.
///
/// assertInitializer ::=
/// 'assert' '(' [Expression] (',' [Expression])? ')'
///
/// Clients may not extend, implement or mix-in this class.
abstract class AssertInitializer implements Assertion, ConstructorInitializer {}
/// An assertion, either in a block or in the initializer list of a constructor.
///
/// Clients may not extend, implement or mix-in this class.
abstract class Assertion implements AstNode {
/// Return the token representing the 'assert' keyword.
Token get assertKeyword;
/// Return the comma between the [condition] and the [message], or `null` if
/// no message was supplied.
Token? get comma;
/// Return the condition that is being asserted to be `true`.
Expression get condition;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the message to report if the assertion fails, or `null` if no
/// message was supplied.
Expression? get message;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// An assert statement.
///
/// assertStatement ::=
/// 'assert' '(' [Expression] (',' [Expression])? ')' ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class AssertStatement implements Assertion, Statement {
/// Return the semicolon terminating the statement.
Token get semicolon;
}
/// An assignment expression.
///
/// assignmentExpression ::=
/// [Expression] operator [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class AssignmentExpression
implements
NullShortableExpression,
MethodReferenceExpression,
CompoundAssignmentExpression {
/// Return the expression used to compute the left hand side.
Expression get leftHandSide;
/// Return the assignment operator being applied.
Token get operator;
/// Return the expression used to compute the right hand side.
Expression get rightHandSide;
}
/// A node in the AST structure for a Dart program.
///
/// Clients may not extend, implement or mix-in this class.
abstract class AstNode implements SyntacticEntity {
/// A comparator that can be used to sort AST nodes in lexical order.
///
/// In other words, `compare` will return a negative value if the offset of
/// the first node is less than the offset of the second node, zero (0) if
/// the nodes have the same offset, and a positive value if the offset of the
/// first node is greater than the offset of the second node.
static Comparator<AstNode> LEXICAL_ORDER =
(AstNode first, AstNode second) => first.offset - second.offset;
/// Return the first token included in this node's source range.
Token get beginToken;
/// Return an iterator that can be used to iterate through all the entities
/// (either AST nodes or tokens) that make up the contents of this node,
/// including doc comments but excluding other comments.
Iterable<SyntacticEntity> get childEntities;
/// Return the offset of the character immediately following the last
/// character of this node's source range.
///
/// This is equivalent to `node.getOffset() + node.getLength()`. For a
/// compilation unit this will be equal to the length of the unit's source.
/// For synthetic nodes this will be equivalent to the node's offset (because
/// the length is zero (0) by definition).
@override
int get end;
/// Return the last token included in this node's source range.
Token get endToken;
/// Return `true` if this node is a synthetic node.
///
/// A synthetic node is a node that was introduced by the parser in order to
/// recover from an error in the code. Synthetic nodes always have a length
/// of zero (`0`).
bool get isSynthetic;
@override
int get length;
@override
int get offset;
/// Return this node's parent node, or `null` if this node is the root of an
/// AST structure.
///
/// Note that the relationship between an AST node and its parent node may
/// change over the lifetime of a node.
AstNode? get parent;
/// Return the node at the root of this node's AST structure.
///
/// Note that this method's performance is linear with respect to the depth
/// of the node in the AST structure (O(depth)).
AstNode get root;
/// Use the given [visitor] to visit this node.
///
/// Return the value returned by the visitor as a result of visiting this
/// node.
E? accept<E>(AstVisitor<E> visitor);
/// Return the token before [target] or `null` if it cannot be found.
Token? findPrevious(Token target);
/// Return the value of the property with the given [name], or `null` if this
/// node does not have a property with the given name.
E? getProperty<E>(String name);
/// Set the value of the property with the given [name] to the given [value].
/// If the value is `null`, the property will effectively be removed.
void setProperty(String name, Object? value);
/// Return either this node or the most immediate ancestor of this node for
/// which the [predicate] returns `true`, or `null` if there is no such node.
E? thisOrAncestorMatching<E extends AstNode>(Predicate<AstNode> predicate);
/// Return either this node or the most immediate ancestor of this node that
/// has the given type, or `null` if there is no such node.
E? thisOrAncestorOfType<E extends AstNode>();
/// Return a textual description of this node in a form approximating valid
/// source.
///
/// The returned string will not be valid source primarily in the case where
/// the node itself is not well-formed.
String toSource();
/// Use the given [visitor] to visit all of the children of this node.
///
/// The children will be visited in lexical order.
void visitChildren(AstVisitor visitor);
}
/// An object that can be used to visit an AST 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/ast/visitor.dart`. A couple of the most useful
/// include
/// * SimpleAstVisitor which implements every visit method by doing nothing,
/// * RecursiveAstVisitor which will cause every node in a structure to be
/// visited, and
/// * ThrowingAstVisitor which implements every visit method by throwing an
/// exception.
abstract class AstVisitor<R> {
R? visitAdjacentStrings(AdjacentStrings node);
R? visitAnnotation(Annotation node);
R? visitArgumentList(ArgumentList node);
R? visitAsExpression(AsExpression node);
R? visitAssertInitializer(AssertInitializer node);
R? visitAssertStatement(AssertStatement assertStatement);
R? visitAssignmentExpression(AssignmentExpression node);
R? visitAwaitExpression(AwaitExpression node);
R? visitBinaryExpression(BinaryExpression node);
R? visitBlock(Block node);
R? visitBlockFunctionBody(BlockFunctionBody node);
R? visitBooleanLiteral(BooleanLiteral node);
R? visitBreakStatement(BreakStatement node);
R? visitCascadeExpression(CascadeExpression node);
R? visitCatchClause(CatchClause node);
R? visitClassDeclaration(ClassDeclaration node);
R? visitClassTypeAlias(ClassTypeAlias node);
R? visitComment(Comment node);
R? visitCommentReference(CommentReference node);
R? visitCompilationUnit(CompilationUnit node);
R? visitConditionalExpression(ConditionalExpression node);
R? visitConfiguration(Configuration node);
R? visitConstructorDeclaration(ConstructorDeclaration node);
R? visitConstructorFieldInitializer(ConstructorFieldInitializer node);
R? visitConstructorName(ConstructorName node);
R? visitConstructorReference(ConstructorReference node);
R? visitContinueStatement(ContinueStatement node);
R? visitDeclaredIdentifier(DeclaredIdentifier node);
R? visitDefaultFormalParameter(DefaultFormalParameter node);
R? visitDoStatement(DoStatement node);
R? visitDottedName(DottedName node);
R? visitDoubleLiteral(DoubleLiteral node);
R? visitEmptyFunctionBody(EmptyFunctionBody node);
R? visitEmptyStatement(EmptyStatement node);
R? visitEnumConstantDeclaration(EnumConstantDeclaration node);
R? visitEnumDeclaration(EnumDeclaration node);
R? visitExportDirective(ExportDirective node);
R? visitExpressionFunctionBody(ExpressionFunctionBody node);
R? visitExpressionStatement(ExpressionStatement node);
R? visitExtendsClause(ExtendsClause node);
R? visitExtensionDeclaration(ExtensionDeclaration node);
R? visitExtensionOverride(ExtensionOverride node);
R? visitFieldDeclaration(FieldDeclaration node);
R? visitFieldFormalParameter(FieldFormalParameter node);
R? visitForEachPartsWithDeclaration(ForEachPartsWithDeclaration node);
R? visitForEachPartsWithIdentifier(ForEachPartsWithIdentifier node);
R? visitForElement(ForElement node);
R? visitFormalParameterList(FormalParameterList node);
R? visitForPartsWithDeclarations(ForPartsWithDeclarations node);
R? visitForPartsWithExpression(ForPartsWithExpression node);
R? visitForStatement(ForStatement node);
R? visitFunctionDeclaration(FunctionDeclaration node);
R? visitFunctionDeclarationStatement(FunctionDeclarationStatement node);
R? visitFunctionExpression(FunctionExpression node);
R? visitFunctionExpressionInvocation(FunctionExpressionInvocation node);
R? visitFunctionReference(FunctionReference node);
R? visitFunctionTypeAlias(FunctionTypeAlias functionTypeAlias);
R? visitFunctionTypedFormalParameter(FunctionTypedFormalParameter node);
R? visitGenericFunctionType(GenericFunctionType node);
R? visitGenericTypeAlias(GenericTypeAlias node);
R? visitHideCombinator(HideCombinator node);
R? visitIfElement(IfElement node);
R? visitIfStatement(IfStatement node);
R? visitImplementsClause(ImplementsClause node);
R? visitImportDirective(ImportDirective node);
R? visitIndexExpression(IndexExpression node);
R? visitInstanceCreationExpression(InstanceCreationExpression node);
R? visitIntegerLiteral(IntegerLiteral node);
R? visitInterpolationExpression(InterpolationExpression node);
R? visitInterpolationString(InterpolationString node);
R? visitIsExpression(IsExpression node);
R? visitLabel(Label node);
R? visitLabeledStatement(LabeledStatement node);
R? visitLibraryDirective(LibraryDirective node);
R? visitLibraryIdentifier(LibraryIdentifier node);
R? visitListLiteral(ListLiteral node);
R? visitMapLiteralEntry(MapLiteralEntry node);
R? visitMethodDeclaration(MethodDeclaration node);
R? visitMethodInvocation(MethodInvocation node);
R? visitMixinDeclaration(MixinDeclaration node);
R? visitNamedExpression(NamedExpression node);
R? visitNativeClause(NativeClause node);
R? visitNativeFunctionBody(NativeFunctionBody node);
R? visitNullLiteral(NullLiteral node);
R? visitOnClause(OnClause node);
R? visitParenthesizedExpression(ParenthesizedExpression node);
R? visitPartDirective(PartDirective node);
R? visitPartOfDirective(PartOfDirective node);
R? visitPostfixExpression(PostfixExpression node);
R? visitPrefixedIdentifier(PrefixedIdentifier node);
R? visitPrefixExpression(PrefixExpression node);
R? visitPropertyAccess(PropertyAccess node);
R? visitRedirectingConstructorInvocation(
RedirectingConstructorInvocation node);
R? visitRethrowExpression(RethrowExpression node);
R? visitReturnStatement(ReturnStatement node);
R? visitScriptTag(ScriptTag node);
R? visitSetOrMapLiteral(SetOrMapLiteral node);
R? visitShowCombinator(ShowCombinator node);
R? visitSimpleFormalParameter(SimpleFormalParameter node);
R? visitSimpleIdentifier(SimpleIdentifier node);
R? visitSimpleStringLiteral(SimpleStringLiteral node);
R? visitSpreadElement(SpreadElement node);
R? visitStringInterpolation(StringInterpolation node);
R? visitSuperConstructorInvocation(SuperConstructorInvocation node);
R? visitSuperExpression(SuperExpression node);
R? visitSwitchCase(SwitchCase node);
R? visitSwitchDefault(SwitchDefault node);
R? visitSwitchStatement(SwitchStatement node);
R? visitSymbolLiteral(SymbolLiteral node);
R? visitThisExpression(ThisExpression node);
R? visitThrowExpression(ThrowExpression node);
R? visitTopLevelVariableDeclaration(TopLevelVariableDeclaration node);
R? visitTryStatement(TryStatement node);
R? visitTypeArgumentList(TypeArgumentList node);
R? visitTypeLiteral(TypeLiteral node);
R? visitTypeName(TypeName node);
R? visitTypeParameter(TypeParameter node);
R? visitTypeParameterList(TypeParameterList node);
R? visitVariableDeclaration(VariableDeclaration node);
R? visitVariableDeclarationList(VariableDeclarationList node);
R? visitVariableDeclarationStatement(VariableDeclarationStatement node);
R? visitWhileStatement(WhileStatement node);
R? visitWithClause(WithClause node);
R? visitYieldStatement(YieldStatement node);
}
/// An await expression.
///
/// awaitExpression ::=
/// 'await' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class AwaitExpression implements Expression {
/// Return the 'await' keyword.
Token get awaitKeyword;
/// Return the expression whose value is being waited on.
Expression get expression;
}
/// A binary (infix) expression.
///
/// binaryExpression ::=
/// [Expression] [Token] [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class BinaryExpression
implements Expression, MethodReferenceExpression {
/// Return the expression used to compute the left operand.
Expression get leftOperand;
/// Return the binary operator being applied.
Token get operator;
/// Return the expression used to compute the right operand.
Expression get rightOperand;
/// The function type of the invocation, or `null` if the AST structure has
/// not been resolved, or if the invocation could not be resolved.
FunctionType? get staticInvokeType;
}
/// A sequence of statements.
///
/// block ::=
/// '{' statement* '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class Block implements Statement {
/// Return the left curly bracket.
Token get leftBracket;
/// Return the right curly bracket.
Token get rightBracket;
/// Return the statements contained in the block.
NodeList<Statement> get statements;
}
/// A function body that consists of a block of statements.
///
/// blockFunctionBody ::=
/// ('async' | 'async' '*' | 'sync' '*')? [Block]
///
/// Clients may not extend, implement or mix-in this class.
abstract class BlockFunctionBody implements FunctionBody {
/// Return the block representing the body of the function.
Block get block;
}
/// A boolean literal expression.
///
/// booleanLiteral ::=
/// 'false' | 'true'
///
/// Clients may not extend, implement or mix-in this class.
abstract class BooleanLiteral implements Literal {
/// Return the token representing the literal.
Token get literal;
/// Return the value of the literal.
bool get value;
}
/// A break statement.
///
/// breakStatement ::=
/// 'break' [SimpleIdentifier]? ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class BreakStatement implements Statement {
/// Return the token representing the 'break' keyword.
Token get breakKeyword;
/// Return the label associated with the statement, or `null` if there is no
/// label.
SimpleIdentifier? get label;
/// Return the semicolon terminating the statement.
Token get semicolon;
/// Return the node from which this break statement is breaking.
///
/// This will be either a [Statement] (in the case of breaking out of a
/// loop), a [SwitchMember] (in the case of a labeled break statement whose
/// label matches a label on a switch case in an enclosing switch statement),
/// or `null` if the AST has not yet been resolved or if the target could not
/// be resolved. Note that if the source code has errors, the target might be
/// invalid (e.g. trying to break to a switch case).
AstNode? get target;
}
/// A sequence of cascaded expressions: expressions that share a common target.
///
/// There are three kinds of expressions that can be used in a cascade
/// expression: [IndexExpression], [MethodInvocation] and [PropertyAccess].
///
/// cascadeExpression ::=
/// [Expression] cascadeSection*
///
/// cascadeSection ::=
/// ('..' | '?..') (cascadeSelector arguments*)
/// (assignableSelector arguments*)*
/// (assignmentOperator expressionWithoutCascade)?
///
/// cascadeSelector ::=
/// '[ ' expression '] '
/// | identifier
///
/// Clients may not extend, implement or mix-in this class.
abstract class CascadeExpression
implements Expression, NullShortableExpression {
/// Return the cascade sections sharing the common target.
NodeList<Expression> get cascadeSections;
/// Whether this cascade is null aware (as opposed to non-null).
bool get isNullAware;
/// Return the target of the cascade sections.
Expression get target;
}
/// A catch clause within a try statement.
///
/// onPart ::=
/// catchPart [Block]
/// | 'on' type catchPart? [Block]
///
/// catchPart ::=
/// 'catch' '(' [SimpleIdentifier] (',' [SimpleIdentifier])? ')'
///
/// Clients may not extend, implement or mix-in this class.
abstract class CatchClause implements AstNode {
/// Return the body of the catch block.
Block get body;
/// Return the token representing the 'catch' keyword, or `null` if there is
/// no 'catch' keyword.
Token? get catchKeyword;
/// Return the comma separating the exception parameter from the stack trace
/// parameter, or `null` if there is no stack trace parameter.
Token? get comma;
/// Return the parameter whose value will be the exception that was thrown, or
/// `null` if there is no 'catch' keyword.
SimpleIdentifier? get exceptionParameter;
/// Return the type of exceptions caught by this catch clause, or `null` if
/// this catch clause catches every type of exception.
TypeAnnotation? get exceptionType;
/// Return the left parenthesis, or `null` if there is no 'catch' keyword.
Token? get leftParenthesis;
/// Return the token representing the 'on' keyword, or `null` if there is no
/// 'on' keyword.
Token? get onKeyword;
/// Return the right parenthesis, or `null` if there is no 'catch' keyword.
Token? get rightParenthesis;
/// Return the parameter whose value will be the stack trace associated with
/// the exception, or `null` if there is no stack trace parameter.
SimpleIdentifier? get stackTraceParameter;
}
/// The declaration of a class.
///
/// classDeclaration ::=
/// 'abstract'? 'class' [SimpleIdentifier] [TypeParameterList]?
/// ([ExtendsClause] [WithClause]?)?
/// [ImplementsClause]?
/// '{' [ClassMember]* '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassDeclaration implements ClassOrMixinDeclaration {
/// Return the 'abstract' keyword, or `null` if the keyword was absent.
Token? get abstractKeyword;
/// Return the token representing the 'class' keyword.
Token get classKeyword;
/// Return the extends clause for this class, or `null` if the class does not
/// extend any other class.
ExtendsClause? get extendsClause;
/// Return `true` if this class is declared to be an abstract class.
bool get isAbstract;
/// Return the native clause for this class, or `null` if the class does not
/// have a native clause.
NativeClause? get nativeClause;
/// Return the with clause for the class, or `null` if the class does not have
/// a with clause.
WithClause? get withClause;
/// Return the constructor declared in the class with the given [name], or
/// `null` if there is no such constructor.
///
/// If the [name] is `null` then the default constructor will be searched
/// for.
ConstructorDeclaration? getConstructor(String? name);
}
/// A node that declares a name within the scope of a class declarations.
///
/// When the 'extension-methods' experiment is enabled, these nodes can also be
/// located inside extension declarations.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassMember implements Declaration {}
/// The declaration of a class or mixin.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassOrMixinDeclaration implements NamedCompilationUnitMember {
@override
ClassElement? get declaredElement;
/// Returns the implements clause for the class/mixin, or `null` if the
/// class/mixin does not implement any interfaces.
ImplementsClause? get implementsClause;
/// Returns the left curly bracket.
Token get leftBracket;
/// Returns the members defined by the class/mixin.
NodeList<ClassMember> get members;
@override
SimpleIdentifier get name;
/// Returns the right curly bracket.
Token get rightBracket;
/// Returns the type parameters for the class/mixin, or `null` if the
/// class/mixin does not have any type parameters.
TypeParameterList? get typeParameters;
/// Returns the field declared in the class/mixin with the given [name], or
/// `null` if there is no such field.
VariableDeclaration? getField(String name);
/// Returns the method declared in the class/mixin with the given [name], or
/// `null` if there is no such method.
MethodDeclaration? getMethod(String name);
}
/// A class type alias.
///
/// classTypeAlias ::=
/// [SimpleIdentifier] [TypeParameterList]? '=' 'abstract'? mixinApplication
///
/// mixinApplication ::=
/// [TypeName] [WithClause] [ImplementsClause]? ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ClassTypeAlias implements TypeAlias {
/// Return the token for the 'abstract' keyword, or `null` if this is not
/// defining an abstract class.
Token? get abstractKeyword;
@override
ClassElement? get declaredElement;
/// Return the token for the '=' separating the name from the definition.
Token get equals;
/// Return the implements clause for this class, or `null` if there is no
/// implements clause.
ImplementsClause? get implementsClause;
/// Return `true` if this class is declared to be an abstract class.
bool get isAbstract;
@override
SimpleIdentifier get name;
/// Return the name of the superclass of the class being declared.
TypeName get superclass;
/// Return the type parameters for the class, or `null` if the class does not
/// have any type parameters.
TypeParameterList? get typeParameters;
/// Return the with clause for this class.
WithClause get withClause;
}
/// An element in a list, map or set literal.
///
/// collectionElement ::=
/// [Expression]
/// | [IfElement]
/// | [ForElement]
/// | [MapLiteralEntry]
/// | [SpreadElement]
///
/// Clients may not extend, implement or mix-in this class.
abstract class CollectionElement implements AstNode {}
/// A combinator associated with an import or export directive.
///
/// combinator ::=
/// [HideCombinator]
/// | [ShowCombinator]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Combinator implements AstNode {
/// Return the 'hide' or 'show' keyword specifying what kind of processing is
/// to be done on the names.
Token get keyword;
}
/// A comment within the source code.
///
/// comment ::=
/// endOfLineComment
/// | blockComment
/// | documentationComment
///
/// endOfLineComment ::=
/// '//' (CHARACTER - EOL)* EOL
///
/// blockComment ::=
/// '/ *' CHARACTER* '&#42;/'
///
/// documentationComment ::=
/// '/ **' (CHARACTER | [CommentReference])* '&#42;/'
/// | ('///' (CHARACTER - EOL)* EOL)+
///
/// Clients may not extend, implement or mix-in this class.
abstract class Comment implements AstNode {
/// Return `true` if this is a block comment.
bool get isBlock;
/// Return `true` if this is a documentation comment.
bool get isDocumentation;
/// Return `true` if this is an end-of-line comment.
bool get isEndOfLine;
/// Return the references embedded within the documentation comment.
NodeList<CommentReference> get references;
/// Return the tokens representing the comment.
List<Token> get tokens;
}
/// A reference to a Dart element that is found within a documentation comment.
///
/// commentReference ::=
/// '[' 'new'? [Identifier] ']'
///
/// Clients may not extend, implement or mix-in this class.
abstract class CommentReference implements AstNode {
/// Return the identifier being referenced.
Identifier get identifier;
/// Return the token representing the 'new' keyword, or `null` if there was no
/// 'new' keyword.
Token? get newKeyword;
}
/// A compilation unit.
///
/// While the grammar restricts the order of the directives and declarations
/// within a compilation unit, this class does not enforce those restrictions.
/// In particular, the children of a compilation unit will be visited in lexical
/// order even if lexical order does not conform to the restrictions of the
/// grammar.
///
/// compilationUnit ::=
/// directives declarations
///
/// directives ::=
/// [ScriptTag]? [LibraryDirective]? namespaceDirective* [PartDirective]*
/// | [PartOfDirective]
///
/// namespaceDirective ::=
/// [ImportDirective]
/// | [ExportDirective]
///
/// declarations ::=
/// [CompilationUnitMember]*
///
/// Clients may not extend, implement or mix-in this class.
abstract class CompilationUnit implements AstNode {
/// Return the declarations contained in this compilation unit.
NodeList<CompilationUnitMember> get declarations;
/// Return the element associated with this compilation unit, or `null` if the
/// AST structure has not been resolved.
CompilationUnitElement? get declaredElement;
/// Return the directives contained in this compilation unit.
NodeList<Directive> get directives;
/// The set of features available to this compilation unit.
///
/// Determined by some combination of the .packages file, the enclosing
/// package's SDK version constraint, and/or the presence of a `@dart`
/// directive in a comment at the top of the file.
FeatureSet get featureSet;
/// The language version override specified for this compilation unit using a
/// token like '// @dart = 2.7', or `null` if no override is specified.
LanguageVersionToken? get languageVersionToken;
/// Return the line information for this compilation unit.
LineInfo? get lineInfo;
/// Return the script tag at the beginning of the compilation unit, or `null`
/// if there is no script tag in this compilation unit.
ScriptTag? get scriptTag;
/// Return a list containing all of the directives and declarations in this
/// compilation unit, sorted in lexical order.
List<AstNode> get sortedDirectivesAndDeclarations;
}
/// A node that declares one or more names within the scope of a compilation
/// unit.
///
/// compilationUnitMember ::=
/// [ClassDeclaration]
/// | [MixinDeclaration]
/// | [ExtensionDeclaration]
/// | [EnumDeclaration]
/// | [TypeAlias]
/// | [FunctionDeclaration]
/// | [TopLevelVariableDeclaration]
///
/// Clients may not extend, implement or mix-in this class.
abstract class CompilationUnitMember implements Declaration {}
/// A potentially compound assignment.
///
/// A compound assignment is any node in which a single expression is used to
/// specify both where to access a value to be operated on (the "read") and to
/// specify where to store the result of the operation (the "write"). This
/// happens in an [AssignmentExpression] when the assignment operator is a
/// compound assignment operator, and in a [PrefixExpression] or
/// [PostfixExpression] when the operator is an increment operator.
///
/// Clients may not extend, implement or mix-in this class.
abstract class CompoundAssignmentExpression implements Expression {
/// The element that is used to read the value.
///
/// If this node is not a compound assignment, this element is `null`.
///
/// In valid code this element can be a [LocalVariableElement], a
/// [ParameterElement], or a [PropertyAccessorElement] getter.
///
/// In invalid code this element is `null`, for example `int += 2`. For
/// recovery [writeElement] is filled, and can be used for navigation.
///
/// This element is `null` if the AST structure has not been resolved, or
/// if the target could not be resolved.
Element? get readElement;
/// The type of the value read with the [readElement].
///
/// If this node is not a compound assignment, this type is `null`.
///
/// In invalid code, e.g. `int += 2`, this type is `dynamic`.
///
/// This type is `null` if the AST structure has not been resolved.
///
/// If the target could not be resolved, this type is `dynamic`.
DartType? get readType;
/// The element that is used to write the result.
///
/// In valid code this is a [LocalVariableElement], [ParameterElement], or a
/// [PropertyAccessorElement] setter.
///
/// In invalid code, for recovery, we might use other elements, for example a
/// [PropertyAccessorElement] getter `myGetter = 0` even though the getter
/// cannot be used to write a value. We do this to help the user to navigate
/// to the getter, and maybe add the corresponding setter.
///
/// If this node is a compound assignment, e. g. `x += 2`, both [readElement]
/// and [writeElement] could be not `null`.
///
/// This element is `null` if the AST structure has not been resolved, or
/// if the target could not be resolved.
Element? get writeElement;
/// The types of assigned values must be subtypes of this type.
///
/// If the target could not be resolved, this type is `dynamic`.
DartType? get writeType;
}
/// A conditional expression.
///
/// conditionalExpression ::=
/// [Expression] '?' [Expression] ':' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConditionalExpression implements Expression {
/// Return the token used to separate the then expression from the else
/// expression.
Token get colon;
/// Return the condition used to determine which of the expressions is
/// executed next.
Expression get condition;
/// Return the expression that is executed if the condition evaluates to
/// `false`.
Expression get elseExpression;
/// Return the token used to separate the condition from the then expression.
Token get question;
/// Return the expression that is executed if the condition evaluates to
/// `true`.
Expression get thenExpression;
}
/// A configuration in either an import or export directive.
///
/// configuration ::=
/// 'if' '(' test ')' uri
///
/// test ::=
/// dottedName ('==' stringLiteral)?
///
/// dottedName ::=
/// identifier ('.' identifier)*
///
/// Clients may not extend, implement or mix-in this class.
abstract class Configuration implements AstNode {
/// Return the token for the equal operator, or `null` if the condition does
/// not include an equality test.
Token? get equalToken;
/// Return the token for the 'if' keyword.
Token get ifKeyword;
/// Return the token for the left parenthesis.
Token get leftParenthesis;
/// Return the name of the declared variable whose value is being used in the
/// condition.
DottedName get name;
/// Return the token for the right parenthesis.
Token get rightParenthesis;
/// Return the URI of the implementation library to be used if the condition
/// is true.
StringLiteral get uri;
/// Return the source to which the [uri] was resolved.
Source? get uriSource;
/// Return the value to which the value of the declared variable will be
/// compared, or `null` if the condition does not include an equality test.
StringLiteral? get value;
}
/// A constructor declaration.
///
/// constructorDeclaration ::=
/// constructorSignature [FunctionBody]?
/// | constructorName formalParameterList ':' 'this' ('.' [SimpleIdentifier])? arguments
///
/// constructorSignature ::=
/// 'external'? constructorName formalParameterList initializerList?
/// | 'external'? 'factory' factoryName formalParameterList initializerList?
/// | 'external'? 'const' constructorName formalParameterList initializerList?
///
/// constructorName ::=
/// [SimpleIdentifier] ('.' [SimpleIdentifier])?
///
/// factoryName ::=
/// [Identifier] ('.' [SimpleIdentifier])?
///
/// initializerList ::=
/// ':' [ConstructorInitializer] (',' [ConstructorInitializer])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorDeclaration implements ClassMember {
/// Return the body of the constructor.
FunctionBody get body;
/// Return the token for the 'const' keyword, or `null` if the constructor is
/// not a const constructor.
Token? get constKeyword;
@override
ConstructorElement? get declaredElement;
/// Return the token for the 'external' keyword to the given [token].
Token? get externalKeyword;
/// Return the token for the 'factory' keyword, or `null` if the constructor
/// is not a factory constructor.
Token? get factoryKeyword;
/// Return the initializers associated with the constructor.
NodeList<ConstructorInitializer> get initializers;
/// Return the name of the constructor, or `null` if the constructor being
/// declared is unnamed.
SimpleIdentifier? get name;
/// Return the parameters associated with the constructor.
FormalParameterList get parameters;
/// Return the token for the period before the constructor name, or `null` if
/// the constructor being declared is unnamed.
Token? get period;
/// Return the name of the constructor to which this constructor will be
/// redirected, or `null` if this is not a redirecting factory constructor.
ConstructorName? get redirectedConstructor;
/// Return the type of object being created.
///
/// This can be different than the type in which the constructor is being
/// declared if the constructor is the implementation of a factory
/// constructor.
Identifier get returnType;
/// Return the token for the separator (colon or equals) before the
/// initializer list or redirection, or `null` if there are no initializers.
Token? get separator;
}
/// The initialization of a field within a constructor's initialization list.
///
/// fieldInitializer ::=
/// ('this' '.')? [SimpleIdentifier] '=' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorFieldInitializer implements ConstructorInitializer {
/// Return the token for the equal sign between the field name and the
/// expression.
Token get equals;
/// Return the expression computing the value to which the field will be
/// initialized.
Expression get expression;
/// Return the name of the field being initialized.
SimpleIdentifier get fieldName;
/// Return the token for the period after the 'this' keyword, or `null` if
/// there is no 'this' keyword.
Token? get period;
/// Return the token for the 'this' keyword, or `null` if there is no 'this'
/// keyword.
Token? get thisKeyword;
}
/// A node that can occur in the initializer list of a constructor declaration.
///
/// constructorInitializer ::=
/// [SuperConstructorInvocation]
/// | [ConstructorFieldInitializer]
/// | [RedirectingConstructorInvocation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorInitializer implements AstNode {}
/// The name of a constructor.
///
/// constructorName ::=
/// type ('.' identifier)?
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorName implements AstNode, ConstructorReferenceNode {
/// Return the name of the constructor, or `null` if the specified constructor
/// is the unnamed constructor.
SimpleIdentifier? get name;
/// Return the token for the period before the constructor name, or `null` if
/// the specified constructor is the unnamed constructor.
Token? get period;
/// Return the name of the type defining the constructor.
TypeName get type;
}
/// An expression representing a reference to a constructor, e.g. the expression
/// `List.filled` in `var x = List.filled;`.
///
/// Objects of this type are not produced directly by the parser (because the
/// parser cannot tell whether an identifier refers to a type); they are
/// produced at resolution time.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorReference implements Expression {
/// The constructor being referenced.
ConstructorName get constructorName;
}
/// An AST node that makes reference to a constructor.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ConstructorReferenceNode implements AstNode {
/// Return the element associated with the referenced constructor based on
/// static type information, or `null` if the AST structure has not been
/// resolved or if the constructor could not be resolved.
ConstructorElement? get staticElement;
}
/// A continue statement.
///
/// continueStatement ::=
/// 'continue' [SimpleIdentifier]? ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ContinueStatement implements Statement {
/// Return the token representing the 'continue' keyword.
Token get continueKeyword;
/// Return the label associated with the statement, or `null` if there is no
/// label.
SimpleIdentifier? get label;
/// Return the semicolon terminating the statement.
Token get semicolon;
/// Return the node to which this continue statement is continuing.
///
/// This will be either a [Statement] (in the case of continuing a loop), a
/// [SwitchMember] (in the case of continuing from one switch case to
/// another), or `null` if the AST has not yet been resolved or if the target
/// could not be resolved. Note that if the source code has errors, the
/// target might be invalid (e.g. the target may be in an enclosing
/// function).
AstNode? get target;
}
/// A node that represents the declaration of one or more names.
///
/// Each declared name is visible within a name scope.
///
/// Clients may not extend, implement or mix-in this class.
abstract class Declaration implements AnnotatedNode {
/// Return the element associated with this declaration, or `null` if either
/// this node corresponds to a list of declarations or if the AST structure
/// has not been resolved.
Element? get declaredElement;
}
/// The declaration of a single identifier.
///
/// declaredIdentifier ::=
/// [Annotation] finalConstVarOrType [SimpleIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class DeclaredIdentifier implements Declaration {
@override
LocalVariableElement? get declaredElement;
/// Return the name of the variable being declared.
SimpleIdentifier get identifier;
/// 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 the token representing either the 'final', 'const' or 'var'
/// keyword, or `null` if no keyword was used.
Token? get keyword;
/// Return the name of the declared type of the parameter, or `null` if the
/// parameter does not have a declared type.
TypeAnnotation? get type;
}
/// A formal parameter with a default value.
///
/// There are two kinds of parameters that are both represented by this class:
/// named formal parameters and positional formal parameters.
///
/// defaultFormalParameter ::=
/// [NormalFormalParameter] ('=' [Expression])?
///
/// defaultNamedParameter ::=
/// [NormalFormalParameter] (':' [Expression])?
///
/// Clients may not extend, implement or mix-in this class.
abstract class DefaultFormalParameter implements FormalParameter {
/// Return the expression computing the default value for the parameter, or
/// `null` if there is no default value.
Expression? get defaultValue;
/// Return the formal parameter with which the default value is associated.
NormalFormalParameter get parameter;
/// Return the token separating the parameter from the default value, or
/// `null` if there is no default value.
Token? get separator;
}
/// A node that represents a directive.
///
/// directive ::=
/// [ExportDirective]
/// | [ImportDirective]
/// | [LibraryDirective]
/// | [PartDirective]
/// | [PartOfDirective]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Directive implements AnnotatedNode {
/// Return the element associated with this directive, or `null` if the AST
/// structure has not been resolved or if this directive could not be
/// resolved.
Element? get element;
/// Return the token representing the keyword that introduces this directive
/// ('import', 'export', 'library' or 'part').
Token get keyword;
}
/// A do statement.
///
/// doStatement ::=
/// 'do' [Statement] 'while' '(' [Expression] ')' ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class DoStatement implements Statement {
/// Return the body of the loop.
Statement get body;
/// Return the condition that determines when the loop will terminate.
Expression get condition;
/// Return the token representing the 'do' keyword.
Token get doKeyword;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
/// Return the semicolon terminating the statement.
Token get semicolon;
/// Return the token representing the 'while' keyword.
Token get whileKeyword;
}
/// A dotted name, used in a configuration within an import or export directive.
///
/// dottedName ::=
/// [SimpleIdentifier] ('.' [SimpleIdentifier])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class DottedName implements AstNode {
/// Return the components of the identifier.
NodeList<SimpleIdentifier> get components;
}
/// A floating point literal expression.
///
/// doubleLiteral ::=
/// decimalDigit+ ('.' decimalDigit*)? exponent?
/// | '.' decimalDigit+ exponent?
///
/// exponent ::=
/// ('e' | 'E') ('+' | '-')? decimalDigit+
///
/// Clients may not extend, implement or mix-in this class.
abstract class DoubleLiteral implements Literal {
/// Return the token representing the literal.
Token get literal;
/// Return the value of the literal.
double get value;
}
/// An empty function body, which can only appear in constructors or abstract
/// methods.
///
/// emptyFunctionBody ::=
/// ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class EmptyFunctionBody implements FunctionBody {
/// Return the token representing the semicolon that marks the end of the
/// function body.
Token get semicolon;
}
/// An empty statement.
///
/// emptyStatement ::=
/// ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class EmptyStatement implements Statement {
/// Return the semicolon terminating the statement.
Token get semicolon;
}
/// The declaration of an enum constant.
///
/// Clients may not extend, implement or mix-in this class.
abstract class EnumConstantDeclaration implements Declaration {
/// Return the name of the constant.
SimpleIdentifier get name;
}
/// The declaration of an enumeration.
///
/// enumType ::=
/// metadata 'enum' [SimpleIdentifier] '{' [SimpleIdentifier] (',' [SimpleIdentifier])* (',')? '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class EnumDeclaration implements NamedCompilationUnitMember {
/// Return the enumeration constants being declared.
NodeList<EnumConstantDeclaration> get constants;
@override
ClassElement? get declaredElement;
/// Return the 'enum' keyword.
Token get enumKeyword;
/// Return the left curly bracket.
Token get leftBracket;
@override
SimpleIdentifier get name;
/// Return the right curly bracket.
Token get rightBracket;
}
/// An export directive.
///
/// exportDirective ::=
/// [Annotation] 'export' [StringLiteral] [Combinator]* ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExportDirective implements NamespaceDirective {
@override
ExportElement? get element;
}
/// A node that represents an expression.
///
/// expression ::=
/// [AssignmentExpression]
/// | [ConditionalExpression] cascadeSection*
/// | [ThrowExpression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Expression implements CollectionElement {
/// An expression _e_ is said to _occur in a constant context_,
/// * if _e_ is an element of a constant list literal, or a key or value of an
/// entry of a constant map literal.
/// * if _e_ is an actual argument of a constant object expression or of a
/// metadata annotation.
/// * if _e_ is the initializing expression of a constant variable
/// declaration.
/// * if _e_ is a switch case expression.
/// * if _e_ is an immediate subexpression of an expression _e1_ which occurs
/// in a constant context, unless _e1_ is a `throw` expression or a function
/// literal.
///
/// This roughly means that everything which is inside a syntactically
/// constant expression is in a constant context. A `throw` expression is
/// currently not allowed in a constant expression, but extensions affecting
/// that status may be considered. A similar situation arises for function
/// literals.
///
/// Note that the default value of an optional formal parameter is _not_ a
/// constant context. This choice reserves some freedom to modify the
/// semantics of default values.
bool get inConstantContext;
/// Return `true` if this expression is syntactically valid for the LHS of an
/// [AssignmentExpression].
bool get isAssignable;
/// Return the precedence of this expression.
///
/// The precedence is a positive integer value that defines how the source
/// code is parsed into an AST. For example `a * b + c` is parsed as `(a * b)
/// + c` because the precedence of `*` is greater than the precedence of `+`.
Precedence get precedence;
/// If this expression is an argument to an invocation, and the AST structure
/// has been resolved, and the function being invoked is known based on static
/// type information, and this expression corresponds to one of the parameters
/// of the function being invoked, then return the parameter element
/// representing the parameter to which the value of this expression will be
/// bound. Otherwise, return `null`.
ParameterElement? get staticParameterElement;
/// Return the static type of this expression, or `null` if the AST structure
/// has not been resolved.
DartType? get staticType;
/// If this expression is a parenthesized expression, return the result of
/// unwrapping the expression inside the parentheses. Otherwise, return this
/// expression.
Expression get unParenthesized;
}
/// A function body consisting of a single expression.
///
/// expressionFunctionBody ::=
/// 'async'? '=>' [Expression] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExpressionFunctionBody implements FunctionBody {
/// Return the expression representing the body of the function.
Expression get expression;
/// Return the token introducing the expression that represents the body of the
/// function.
Token get functionDefinition;
/// Return the semicolon terminating the statement.
Token? get semicolon;
}
/// An expression used as a statement.
///
/// expressionStatement ::=
/// [Expression]? ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExpressionStatement implements Statement {
/// Return the expression that comprises the statement.
Expression get expression;
/// Return the semicolon terminating the statement, or `null` if the
/// expression is a function expression and therefore isn't followed by a
/// semicolon.
Token? get semicolon;
}
/// The "extends" clause in a class declaration.
///
/// extendsClause ::=
/// 'extends' [TypeName]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExtendsClause implements AstNode {
/// Return the token representing the 'extends' keyword.
Token get extendsKeyword;
/// Return the name of the class that is being extended.
TypeName get superclass;
}
/// The declaration of an extension of a type.
///
/// extension ::=
/// 'extension' [SimpleIdentifier]? [TypeParameterList]?
/// 'on' [TypeAnnotation] '{' [ClassMember]* '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExtensionDeclaration implements CompilationUnitMember {
@override
ExtensionElement? get declaredElement;
/// Return the type that is being extended.
TypeAnnotation get extendedType;
/// Return the token representing the 'extension' keyword.
Token get extensionKeyword;
/// Return the left curly bracket.
Token get leftBracket;
/// Return the members being added to the extended class.
NodeList<ClassMember> get members;
/// Return the name of the extension, or `null` if the extension does not have
/// a name.
SimpleIdentifier? get name;
/// Return the token representing the 'on' keyword.
Token get onKeyword;
/// Return the right curly bracket.
Token get rightBracket;
/// Return the token representing the 'type' keyword.
Token? get typeKeyword;
/// Return the type parameters for the extension, or `null` if the extension
/// does not have any type parameters.
TypeParameterList? get typeParameters;
}
/// An override to force resolution to choose a member from a specific
/// extension.
///
/// extensionOverride ::=
/// [Identifier] [TypeArgumentList]? [ArgumentList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ExtensionOverride implements Expression {
/// Return the list of arguments to the override. In valid code this will
/// contain a single argument, which evaluates to the object being extended.
ArgumentList get argumentList;
/// Return the actual type extended by this override, produced by applying
/// [typeArgumentTypes] to the generic type extended by the extension.
///
/// Return `null` if the AST structure has not been resolved.
DartType? get extendedType;
/// Return the name of the extension being selected.
Identifier get extensionName;
/// Whether this override is null aware (as opposed to non-null).
bool get isNullAware;
/// Return the forced extension element.
///
/// Return `null` if the AST structure has not been resolved.
ExtensionElement? get staticElement;
/// Return the type arguments to be applied to the extension, or `null` if no
/// type arguments were provided.
TypeArgumentList? get typeArguments;
/// Return the actual type arguments to be applied to the extension, either
/// explicitly specified in [typeArguments], or inferred.
///
/// If the AST has been resolved, never returns `null`, returns an empty list
/// if the extension does not have type parameters.
///
/// Return `null` if the AST structure has not been resolved.
List<DartType>? get typeArgumentTypes;
}
/// The declaration of one or more fields of the same type.
///
/// fieldDeclaration ::=
/// 'static' 'const' <type>? <staticFinalDeclarationList>
/// | 'static' 'final' <type>? <staticFinalDeclarationList>
/// | 'static' 'late' 'final' <type>? <initializedIdentifierList>
/// | 'static' 'late'? <varOrType> <initializedIdentifierList>
/// | 'covariant' 'late'? <varOrType> <initializedIdentifierList>
/// | 'late'? 'final' <type>? <initializedIdentifierList>
/// | 'late'? <varOrType> <initializedIdentifierList>
/// | 'external' ('static'? <finalVarOrType> | 'covariant' <varOrType>)
/// <identifierList>
/// | 'abstract' (<finalVarOrType> | 'covariant' <varOrType>)
/// <identifierList>
///
/// (Note: there is no <fieldDeclaration> production in the grammar; this is a
/// subset of the grammar production <declaration>, which encompasses everything
/// that can appear inside a class declaration except methods).
///
/// Prior to the 'extension-methods' experiment, these nodes were always
/// children of a class declaration. When the experiment is enabled, these nodes
/// can also be children of an extension declaration.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FieldDeclaration implements ClassMember {
/// The `abstract` keyword, or `null` if the keyword was not used.
Token? get abstractKeyword;
/// The 'covariant' keyword, or `null` if the keyword was not used.
Token? get covariantKeyword;
/// The `external` keyword, or `null` if the keyword was not used.
Token? get externalKeyword;
/// Return the fields being declared.
VariableDeclarationList get fields;
/// Return `true` if the fields are declared to be static.
bool get isStatic;
/// Return the semicolon terminating the declaration.
Token get semicolon;
/// Return the token representing the 'static' keyword, or `null` if the
/// fields are not static.
Token? get staticKeyword;
}
/// A field formal parameter.
///
/// fieldFormalParameter ::=
/// ('final' [TypeAnnotation] | 'const' [TypeAnnotation] | 'var' | [TypeAnnotation])?
/// 'this' '.' [SimpleIdentifier] ([TypeParameterList]? [FormalParameterList])?
///
/// Clients may not extend, implement or mix-in this class.
abstract class FieldFormalParameter implements NormalFormalParameter {
@override
SimpleIdentifier get identifier;
/// Return the token representing either the 'final', 'const' or 'var'
/// keyword, or `null` if no keyword was used.
Token? get keyword;
/// Return the parameters of the function-typed parameter, or `null` if this
/// is not a function-typed field formal parameter.
FormalParameterList? get parameters;
/// Return the token representing the period.
Token get period;
/// If the parameter is function-typed, and has the question mark, then its
/// function type is nullable. Having a nullable function type means that the
/// parameter can be null.
Token? get question;
/// Return the token representing the 'this' keyword.
Token get thisKeyword;
/// Return the declared type of the parameter, or `null` if the parameter does
/// not have a declared type.
///
/// Note that if this is a function-typed field formal parameter this is the
/// return type of the function.
TypeAnnotation? get type;
/// Return the type parameters associated with this method, or `null` if this
/// method is not a generic method.
TypeParameterList? get typeParameters;
}
/// The parts of a for-each loop that control the iteration.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForEachParts implements ForLoopParts {
/// Return the token representing the 'in' keyword.
Token get inKeyword;
/// Return the expression evaluated to produce the iterator.
Expression get iterable;
}
/// The parts of a for-each loop that control the iteration when the loop
/// variable is declared as part of the for loop.
///
/// forLoopParts ::=
/// [DeclaredIdentifier] 'in' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForEachPartsWithDeclaration implements ForEachParts {
/// Return the declaration of the loop variable.
DeclaredIdentifier get loopVariable;
}
/// The parts of a for-each loop that control the iteration when the loop
/// variable is declared outside of the for loop.
///
/// forLoopParts ::=
/// [SimpleIdentifier] 'in' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForEachPartsWithIdentifier implements ForEachParts {
/// Return the loop variable.
SimpleIdentifier get identifier;
}
/// The basic structure of a for element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForElement implements CollectionElement {
/// Return the token representing the 'await' keyword, or `null` if there was
/// no 'await' keyword.
Token? get awaitKeyword;
/// Return the body of the loop.
CollectionElement get body;
/// Return the token representing the 'for' keyword.
Token get forKeyword;
/// Return the parts of the for element that control the iteration.
ForLoopParts get forLoopParts;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// The parts of a for or for-each loop that control the iteration.
///
/// forLoopParts ::=
/// [VariableDeclaration] ';' [Expression]? ';' expressionList?
/// | [Expression]? ';' [Expression]? ';' expressionList?
/// | [DeclaredIdentifier] 'in' [Expression]
/// | [SimpleIdentifier] 'in' [Expression]
///
/// expressionList ::=
/// [Expression] (',' [Expression])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForLoopParts implements AstNode {}
/// A node representing a parameter to a function.
///
/// formalParameter ::=
/// [NormalFormalParameter]
/// | [DefaultFormalParameter]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FormalParameter implements AstNode {
/// The 'covariant' keyword, or `null` if the keyword was not used.
Token? get covariantKeyword;
/// Return the element representing this parameter, or `null` if this
/// parameter has not been resolved.
ParameterElement? get declaredElement;
/// Return the name of the parameter being declared, or `null` if the
/// parameter doesn't have a name, such as when it's part of a generic
/// function type.
SimpleIdentifier? get identifier;
/// Return `true` if this parameter was declared with the 'const' modifier.
bool get isConst;
/// Return `true` if this parameter was declared with the 'final' modifier.
///
/// Parameters that are declared with the 'const' modifier will return
/// `false` even though they are implicitly final.
bool get isFinal;
/// Return `true` if this parameter is a named parameter.
///
/// Named parameters can either be required or optional.
bool get isNamed;
/// Return `true` if this parameter is an optional parameter.
///
/// Optional parameters can either be positional or named.
bool get isOptional;
/// Return `true` if this parameter is both an optional and named parameter.
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 a required parameter.
///
/// Required parameters can either be positional or named.
///
/// Note: this will return `false` for a named parameter that is annotated
/// with the `@required` annotation.
bool get isRequired;
/// Return `true` if this parameter is both a required and named parameter.
///
/// Note: this will return `false` for a named parameter that is annotated
/// with the `@required` annotation.
bool get isRequiredNamed;
/// Return `true` if this parameter is both a required and positional
/// parameter.
bool get isRequiredPositional;
/// Return the annotations associated with this parameter.
NodeList<Annotation> get metadata;
/// The 'required' keyword, or `null` if the keyword was not used.
Token? get requiredKeyword;
}
/// The formal parameter list of a method declaration, function declaration, or
/// function type alias.
///
/// While the grammar requires all optional formal parameters to follow all of
/// the normal formal parameters and at most one grouping of optional formal
/// parameters, this class does not enforce those constraints. All parameters
/// are flattened into a single list, which can have any or all kinds of
/// parameters (normal, named, and positional) in any order.
///
/// formalParameterList ::=
/// '(' ')'
/// | '(' normalFormalParameters (',' optionalFormalParameters)? ')'
/// | '(' optionalFormalParameters ')'
///
/// normalFormalParameters ::=
/// [NormalFormalParameter] (',' [NormalFormalParameter])*
///
/// optionalFormalParameters ::=
/// optionalPositionalFormalParameters
/// | namedFormalParameters
///
/// optionalPositionalFormalParameters ::=
/// '[' [DefaultFormalParameter] (',' [DefaultFormalParameter])* ']'
///
/// namedFormalParameters ::=
/// '{' [DefaultFormalParameter] (',' [DefaultFormalParameter])* '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class FormalParameterList implements AstNode {
/// Return the left square bracket ('[') or left curly brace ('{') introducing
/// the optional parameters, or `null` if there are no optional parameters.
Token? get leftDelimiter;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return a list containing the elements representing the parameters in this
/// list.
///
/// The list will contain `null`s if the parameters in this list have not
/// been resolved.
List<ParameterElement?> get parameterElements;
/// Return the parameters associated with the method.
NodeList<FormalParameter> get parameters;
/// Return the right square bracket (']') or right curly brace ('}')
/// terminating the optional parameters, or `null` if there are no optional
/// parameters.
Token? get rightDelimiter;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// The parts of a for loop that control the iteration.
///
/// forLoopParts ::=
/// [VariableDeclaration] ';' [Expression]? ';' expressionList?
/// | [Expression]? ';' [Expression]? ';' expressionList?
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForParts implements ForLoopParts {
/// Return the condition used to determine when to terminate the loop, or
/// `null` if there is no condition.
Expression? get condition;
/// Return the semicolon separating the initializer and the condition.
Token get leftSeparator;
/// Return the semicolon separating the condition and the updater.
Token get rightSeparator;
/// Return the list of expressions run after each execution of the loop body.
NodeList<Expression> get updaters;
}
/// The parts of a for loop that control the iteration when there are one or
/// more variable declarations as part of the for loop.
///
/// forLoopParts ::=
/// [VariableDeclarationList] ';' [Expression]? ';' expressionList?
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForPartsWithDeclarations implements ForParts {
/// Return the declaration of the loop variables.
VariableDeclarationList get variables;
}
/// The parts of a for loop that control the iteration when there are no
/// variable declarations as part of the for loop.
///
/// forLoopParts ::=
/// [Expression]? ';' [Expression]? ';' expressionList?
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForPartsWithExpression implements ForParts {
/// Return the initialization expression, or `null` if there is no
/// initialization expression.
Expression? get initialization;
}
/// A for or for-each statement.
///
/// forStatement ::=
/// 'for' '(' forLoopParts ')' [Statement]
///
/// forLoopParts ::=
/// [VariableDeclaration] ';' [Expression]? ';' expressionList?
/// | [Expression]? ';' [Expression]? ';' expressionList?
/// | [DeclaredIdentifier] 'in' [Expression]
/// | [SimpleIdentifier] 'in' [Expression]
///
/// This is the class that is used to represent a for loop when either the
/// 'control-flow-collections' or 'spread-collections' experiments are enabled.
/// If neither of those experiments are enabled, then either `ForStatement` or
/// `ForEachStatement` will be used.
///
/// Clients may not extend, implement or mix-in this class.
abstract class ForStatement implements Statement {
/// Return the token representing the 'await' keyword, or `null` if there is
/// no 'await' keyword.
Token? get awaitKeyword;
/// Return the body of the loop.
Statement get body;
/// Return the token representing the 'for' keyword.
Token get forKeyword;
/// Return the parts of the for element that control the iteration.
ForLoopParts get forLoopParts;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// A node representing the body of a function or method.
///
/// functionBody ::=
/// [BlockFunctionBody]
/// | [EmptyFunctionBody]
/// | [ExpressionFunctionBody]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionBody implements AstNode {
/// Return `true` if this function body is asynchronous.
bool get isAsynchronous;
/// Return `true` if this function body is a generator.
bool get isGenerator;
/// Return `true` if this function body is synchronous.
bool get isSynchronous;
/// Return the token representing the 'async' or 'sync' keyword, or `null` if
/// there is no such keyword.
Token? get keyword;
/// Return the star following the 'async' or 'sync' keyword, or `null` if
/// there is no star.
Token? get star;
/// If [variable] is a local variable or parameter declared anywhere within
/// the top level function or method containing this [FunctionBody], return a
/// boolean indicating whether [variable] is potentially mutated within a
/// local function other than the function in which it is declared.
///
/// If [variable] is not a local variable or parameter declared within the top
/// level function or method containing this [FunctionBody], return `false`.
///
/// Throws an exception if resolution has not yet been performed.
bool isPotentiallyMutatedInClosure(VariableElement variable);
/// If [variable] is a local variable or parameter declared anywhere within
/// the top level function or method containing this [FunctionBody], return a
/// boolean indicating whether [variable] is potentially mutated within the
/// scope of its declaration.
///
/// If [variable] is not a local variable or parameter declared within the top
/// level function or method containing this [FunctionBody], return `false`.
///
/// Throws an exception if resolution has not yet been performed.
bool isPotentiallyMutatedInScope(VariableElement variable);
}
/// A top-level function declaration.
///
/// functionDeclaration ::=
/// 'external' functionSignature
/// | functionSignature [FunctionBody]
///
/// functionSignature ::=
/// [Type]? ('get' | 'set')? [SimpleIdentifier] [FormalParameterList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionDeclaration implements NamedCompilationUnitMember {
@override
ExecutableElement? get declaredElement;
/// Return the token representing the 'external' keyword, or `null` if this is
/// not an external function.
Token? get externalKeyword;
/// Return the function expression being wrapped.
FunctionExpression get functionExpression;
/// Return `true` if this function declares a getter.
bool get isGetter;
/// Return `true` if this function declares a setter.
bool get isSetter;
@override
SimpleIdentifier get name;
/// Return the token representing the 'get' or 'set' keyword, or `null` if
/// this is a function declaration rather than a property declaration.
Token? get propertyKeyword;
/// Return the return type of the function, or `null` if no return type was
/// declared.
TypeAnnotation? get returnType;
}
/// A [FunctionDeclaration] used as a statement.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionDeclarationStatement implements Statement {
/// Return the function declaration being wrapped.
FunctionDeclaration get functionDeclaration;
}
/// A function expression.
///
/// functionExpression ::=
/// [TypeParameterList]? [FormalParameterList] [FunctionBody]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionExpression implements Expression {
/// Return the body of the function.
FunctionBody get body;
/// Return the element associated with the function, or `null` if the AST
/// structure has not been resolved.
ExecutableElement? get declaredElement;
/// Return the parameters associated with the function, or `null` if the
/// function is part of a top-level getter.
FormalParameterList? get parameters;
/// Return the type parameters associated with this method, or `null` if this
/// method is not a generic method.
TypeParameterList? get typeParameters;
}
/// The invocation of a function resulting from evaluating an expression.
///
/// Invocations of methods and other forms of functions are represented by
/// [MethodInvocation] nodes. Invocations of getters and setters are represented
/// by either [PrefixedIdentifier] or [PropertyAccess] nodes.
///
/// functionExpressionInvocation ::=
/// [Expression] [TypeArgumentList]? [ArgumentList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionExpressionInvocation
implements NullShortableExpression, InvocationExpression {
/// Return the expression producing the function being invoked.
@override
Expression get function;
/// Return the element associated with the function being invoked based on
/// static type information, or `null` if the AST structure has not been
/// resolved or the function could not be resolved.
ExecutableElement? get staticElement;
}
/// An expression representing a reference to a function, possibly with type
/// arguments applied to it, e.g. the expression `print` in `var x = print;`.
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionReference implements Expression {
/// The function being referenced.
///
/// In error-free code, this will be either a SimpleIdentifier (indicating a
/// function that is in scope), a PrefixedIdentifier (indicating a either
/// function imported via prefix or a static method in a class), or a
/// PropertyAccess (indicating a static method in a class imported via
/// prefix). In code with errors, this could be other kinds of expressions
/// (e.g. `(...)<int>` parses as a FunctionReference whose referent is a
/// ParenthesizedExpression.
Expression get function;
/// The type arguments being applied to the function, or `null` if there are
/// no type arguments.
TypeArgumentList? get typeArguments;
/// The actual type arguments being applied to the function, either explicitly
/// specified in [typeArguments], or inferred.
///
/// If the AST has been resolved, never returns `null`, returns an empty list
/// if the function does not have type parameters.
///
/// Returns `null` if the AST structure has not been resolved.
List<DartType>? get typeArgumentTypes;
}
/// A function type alias.
///
/// functionTypeAlias ::=
/// functionPrefix [TypeParameterList]? [FormalParameterList] ';'
///
/// functionPrefix ::=
/// [TypeAnnotation]? [SimpleIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionTypeAlias implements TypeAlias {
@override
TypeAliasElement? get declaredElement;
/// Return the parameters associated with the function type.
FormalParameterList get parameters;
/// Return the return type of the function type being defined, or `null` if no
/// return type was given.
TypeAnnotation? get returnType;
/// Return the type parameters for the function type, or `null` if the
/// function type does not have any type parameters.
TypeParameterList? get typeParameters;
}
/// A function-typed formal parameter.
///
/// functionSignature ::=
/// [TypeAnnotation]? [SimpleIdentifier] [TypeParameterList]?
/// [FormalParameterList] '?'?
///
/// Clients may not extend, implement or mix-in this class.
abstract class FunctionTypedFormalParameter implements NormalFormalParameter {
@override
SimpleIdentifier get identifier;
/// Return the parameters of the function-typed parameter.
FormalParameterList get parameters;
/// Return the question mark indicating that the function type is nullable, or
/// `null` if there is no question mark. Having a nullable function type means
/// that the parameter can be null.
Token? get question;
/// Return the return type of the function, or `null` if the function does not
/// have a return type.
TypeAnnotation? get returnType;
/// Return the type parameters associated with this function, or `null` if
/// this function is not a generic function.
TypeParameterList? get typeParameters;
}
/// An anonymous function type.
///
/// functionType ::=
/// [TypeAnnotation]? 'Function' [TypeParameterList]?
/// [FormalParameterList] '?'?
///
/// where the FormalParameterList is being used to represent the following
/// grammar, despite the fact that FormalParameterList can represent a much
/// larger grammar than the one below. This is done in order to simplify the
/// implementation.
///
/// parameterTypeList ::=
/// () |
/// ( normalParameterTypes ,? ) |
/// ( normalParameterTypes , optionalParameterTypes ) |
/// ( optionalParameterTypes )
/// namedParameterTypes ::=
/// { namedParameterType (, namedParameterType)* ,? }
/// namedParameterType ::=
/// [TypeAnnotation]? [SimpleIdentifier]
/// normalParameterTypes ::=
/// normalParameterType (, normalParameterType)*
/// normalParameterType ::=
/// [TypeAnnotation] [SimpleIdentifier]?
/// optionalParameterTypes ::=
/// optionalPositionalParameterTypes | namedParameterTypes
/// optionalPositionalParameterTypes ::=
/// [ normalParameterTypes ,? ]
///
/// Clients may not extend, implement or mix-in this class.
abstract class GenericFunctionType implements TypeAnnotation {
/// Return the keyword 'Function'.
Token get functionKeyword;
/// Return the parameters associated with the function type.
FormalParameterList get parameters;
/// Return the return type of the function type being defined, or `null` if
/// no return type was given.
TypeAnnotation? get returnType;
/// Return the type parameters for the function type, or `null` if the
/// function type does not have any type parameters.
TypeParameterList? get typeParameters;
}
/// A generic type alias.
///
/// functionTypeAlias ::=
/// metadata 'typedef' [SimpleIdentifier] [TypeParameterList]? = [FunctionType] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class GenericTypeAlias implements TypeAlias {
/// Return the equal sign separating the name being defined from the function
/// type.
Token get equals;
/// Return the type of function being defined by the alias.
///
/// When the non-function type aliases feature is enabled and the denoted
/// type is not a [GenericFunctionType], return `null`.
GenericFunctionType? get functionType;
/// Return the type being defined by the alias.
TypeAnnotation get type;
/// Return the type parameters for the function type, or `null` if the
/// function type does not have any type parameters.
TypeParameterList? get typeParameters;
}
/// A combinator that restricts the names being imported to those that are not
/// in a given list.
///
/// hideCombinator ::=
/// 'hide' [SimpleIdentifier] (',' [SimpleIdentifier])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class HideCombinator implements Combinator {
/// Return the list of names from the library that are hidden by this
/// combinator.
NodeList<SimpleIdentifier> get hiddenNames;
}
/// A node that represents an identifier.
///
/// identifier ::=
/// [SimpleIdentifier]
/// | [PrefixedIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Identifier implements Expression {
/// Return the lexical representation of the identifier.
String get name;
/// Return the element associated with this identifier based on static type
/// information, or `null` if the AST structure has not been resolved or if
/// this identifier could not be resolved.
///
/// One example of the latter case is an identifier that is not defined
/// within the scope in which it appears.
Element? get staticElement;
/// Return `true` if the given [name] is visible only within the library in
/// which it is declared.
static bool isPrivateName(String name) => name.isNotEmpty && name[0] == "_";
}
/// The basic structure of an if element.
///
/// Clients may not extend, implement or mix-in this class.
abstract class IfElement implements CollectionElement {
/// Return the condition used to determine which of the statements is executed
/// next.
Expression get condition;
/// Return the statement that is executed if the condition evaluates to
/// `false`, or `null` if there is no else statement.
CollectionElement? get elseElement;
/// Return the token representing the 'else' keyword, or `null` if there is no
/// else statement.
Token? get elseKeyword;
/// Return the token representing the 'if' keyword.
Token get ifKeyword;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
/// Return the statement that is executed if the condition evaluates to
/// `true`.
CollectionElement get thenElement;
}
/// An if statement.
///
/// ifStatement ::=
/// 'if' '(' [Expression] ')' [Statement] ('else' [Statement])?
///
/// Clients may not extend, implement or mix-in this class.
abstract class IfStatement implements Statement {
/// Return the condition used to determine which of the statements is executed
/// next.
Expression get condition;
/// Return the token representing the 'else' keyword, or `null` if there is no
/// else statement.
Token? get elseKeyword;
/// Return the statement that is executed if the condition evaluates to
/// `false`, or `null` if there is no else statement.
Statement? get elseStatement;
/// Return the token representing the 'if' keyword.
Token get ifKeyword;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
/// Return the statement that is executed if the condition evaluates to
/// `true`.
Statement get thenStatement;
}
/// The "implements" clause in an class declaration.
///
/// implementsClause ::=
/// 'implements' [TypeName] (',' [TypeName])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class ImplementsClause implements AstNode {
/// Return the token representing the 'implements' keyword.
Token get implementsKeyword;
/// Return the list of the interfaces that are being implemented.
NodeList<TypeName> get interfaces;
}
/// An import directive.
///
/// importDirective ::=
/// [Annotation] 'import' [StringLiteral] ('as' identifier)? [Combinator]* ';'
/// | [Annotation] 'import' [StringLiteral] 'deferred' 'as' identifier [Combinator]* ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ImportDirective implements NamespaceDirective {
static Comparator<ImportDirective> COMPARATOR =
(ImportDirective import1, ImportDirective import2) {
//
// uri
//
StringLiteral uri1 = import1.uri;
StringLiteral uri2 = import2.uri;
String? uriStr1 = uri1.stringValue;
String? uriStr2 = uri2.stringValue;
if (uriStr1 != null || uriStr2 != null) {
if (uriStr1 == null) {
return -1;
} else if (uriStr2 == null) {
return 1;
} else {
int compare = uriStr1.compareTo(uriStr2);
if (compare != 0) {
return compare;
}
}
}
//
// as
//
SimpleIdentifier? prefix1 = import1.prefix;
SimpleIdentifier? prefix2 = import2.prefix;
String? prefixStr1 = prefix1?.name;
String? prefixStr2 = prefix2?.name;
if (prefixStr1 != null || prefixStr2 != null) {
if (prefixStr1 == null) {
return -1;
} else if (prefixStr2 == null) {
return 1;
} else {
int compare = prefixStr1.compareTo(prefixStr2);
if (compare != 0) {
return compare;
}
}
}
//
// hides and shows
//
NodeList<Combinator> combinators1 = import1.combinators;
List<String> allHides1 = <String>[];
List<String> allShows1 = <String>[];
int length1 = combinators1.length;
for (int i = 0; i < length1; i++) {
Combinator combinator = combinators1[i];
if (combinator is HideCombinator) {
NodeList<SimpleIdentifier> hides = combinator.hiddenNames;
int hideLength = hides.length;
for (int j = 0; j < hideLength; j++) {
SimpleIdentifier simpleIdentifier = hides[j];
allHides1.add(simpleIdentifier.name);
}
} else {
NodeList<SimpleIdentifier> shows =
(combinator as ShowCombinator).shownNames;
int showLength = shows.length;
for (int j = 0; j < showLength; j++) {
SimpleIdentifier simpleIdentifier = shows[j];
allShows1.add(simpleIdentifier.name);
}
}
}
NodeList<Combinator> combinators2 = import2.combinators;
List<String> allHides2 = <String>[];
List<String> allShows2 = <String>[];
int length2 = combinators2.length;
for (int i = 0; i < length2; i++) {
Combinator combinator = combinators2[i];
if (combinator is HideCombinator) {
NodeList<SimpleIdentifier> hides = combinator.hiddenNames;
int hideLength = hides.length;
for (int j = 0; j < hideLength; j++) {
SimpleIdentifier simpleIdentifier = hides[j];
allHides2.add(simpleIdentifier.name);
}
} else {
NodeList<SimpleIdentifier> shows =
(combinator as ShowCombinator).shownNames;
int showLength = shows.length;
for (int j = 0; j < showLength; j++) {
SimpleIdentifier simpleIdentifier = shows[j];
allShows2.add(simpleIdentifier.name);
}
}
}
// test lengths of combinator lists first
if (allHides1.length != allHides2.length) {
return allHides1.length - allHides2.length;
}
if (allShows1.length != allShows2.length) {
return allShows1.length - allShows2.length;
}
// next ensure that the lists are equivalent
if (!allHides1.toSet().containsAll(allHides2)) {
return -1;
}
if (!allShows1.toSet().containsAll(allShows2)) {
return -1;
}
return 0;
};
/// Return the token representing the 'as' keyword, or `null` if the imported
/// names are not prefixed.
Token? get asKeyword;
/// Return the token representing the 'deferred' keyword, or `null` if the
/// imported URI is not deferred.
Token? get deferredKeyword;
@override
ImportElement? get element;
/// Return the prefix to be used with the imported names, or `null` if the
/// imported names are not prefixed.
SimpleIdentifier? get prefix;
}
/// An index expression.
///
/// indexExpression ::=
/// [Expression] '[' [Expression] ']'
///
/// Clients may not extend, implement or mix-in this class.
abstract class IndexExpression
implements NullShortableExpression, MethodReferenceExpression {
/// Return the expression used to compute the index.
Expression get index;
/// Return `true` if this expression is cascaded.
///
/// If it is, then the target of this expression is not stored locally but is
/// stored in the nearest ancestor that is a [CascadeExpression].
bool get isCascaded;
/// Whether this index expression is null aware (as opposed to non-null).
bool get isNullAware;
/// Return the left square bracket.
Token get leftBracket;
/// Return the period (".." | "?..") before a cascaded index expression, or
/// `null` if this index expression is not part of a cascade expression.
Token? get period;
/// Return the question mark before the left bracket, or `null` if there is no
/// question mark.
Token? get question;
/// Return the expression used to compute the object being indexed.
///
/// If this index expression is not part of a cascade expression, then this
/// is the same as [target]. If this index expression is part of a cascade
/// expression, then the target expression stored with the cascade expression
/// is returned.
Expression get realTarget;
/// Return the right square bracket.
Token get rightBracket;
/// Return the expression used to compute the object being indexed, or `null`
/// if this index expression is part of a cascade expression.
///
/// Use [realTarget] to get the target independent of whether this is part of
/// a cascade expression.
Expression? get target;
/// Return `true` if this expression is computing a right-hand value (that is,
/// if this expression is in a context where the operator '[]' will be
/// invoked).
///
/// Note that [inGetterContext] and [inSetterContext] are not opposites, nor
/// are they mutually exclusive. In other words, it is possible for both
/// methods to return `true` when invoked on the same node.
// TODO(brianwilkerson) Convert this to a getter.
bool inGetterContext();
/// Return `true` if this expression is computing a left-hand value (that is,
/// if this expression is in a context where the operator '[]=' will be
/// invoked).
///
/// Note that [inGetterContext] and [inSetterContext] are not opposites, nor
/// are they mutually exclusive. In other words, it is possible for both
/// methods to return `true` when invoked on the same node.
// TODO(brianwilkerson) Convert this to a getter.
bool inSetterContext();
}
/// An instance creation expression.
///
/// newExpression ::=
/// ('new' | 'const')? [TypeName] ('.' [SimpleIdentifier])? [ArgumentList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class InstanceCreationExpression implements Expression {
/// Return the list of arguments to the constructor.
ArgumentList get argumentList;
/// Return the name of the constructor to be invoked.
ConstructorName get constructorName;
/// Return `true` if this creation expression is used to invoke a constant
/// constructor, either because the keyword `const` was explicitly provided or
/// because no keyword was provided and this expression is in a constant
/// context.
bool get isConst;
/// Return the 'new' or 'const' keyword used to indicate how an object should
/// be created, or `null` if the keyword was not explicitly provided.
Token? get keyword;
}
/// An integer literal expression.
///
/// integerLiteral ::=
/// decimalIntegerLiteral
/// | hexadecimalIntegerLiteral
///
/// decimalIntegerLiteral ::=
/// decimalDigit+
///
/// hexadecimalIntegerLiteral ::=
/// '0x' hexadecimalDigit+
/// | '0X' hexadecimalDigit+
///
/// Clients may not extend, implement or mix-in this class.
abstract class IntegerLiteral implements Literal {
/// Return the token representing the literal.
Token get literal;
/// Return the value of the literal, or `null` when [literal] does not
/// represent a valid `int` value, for example because of overflow.
int? get value;
}
/// A node within a [StringInterpolation].
///
/// interpolationElement ::=
/// [InterpolationExpression]
/// | [InterpolationString]
///
/// Clients may not extend, implement or mix-in this class.
abstract class InterpolationElement implements AstNode {}
/// An expression embedded in a string interpolation.
///
/// interpolationExpression ::=
/// '$' [SimpleIdentifier]
/// | '$' '{' [Expression] '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class InterpolationExpression implements InterpolationElement {
/// Return the expression to be evaluated for the value to be converted into a
/// string.
Expression get expression;
/// Return the token used to introduce the interpolation expression; either
/// '$' if the expression is a simple identifier or '${' if the expression is
/// a full expression.
Token get leftBracket;
/// Return the right curly bracket, or `null` if the expression is an
/// identifier without brackets.
Token? get rightBracket;
}
/// A non-empty substring of an interpolated string.
///
/// interpolationString ::=
/// characters
///
/// Clients may not extend, implement or mix-in this class.
abstract class InterpolationString implements InterpolationElement {
/// Return the characters that will be added to the string.
Token get contents;
/// Return the offset of the after-last contents character.
int get contentsEnd;
/// Return the offset of the first contents character.
int get contentsOffset;
/// Return the value of the literal.
String get value;
}
/// The invocation of a function or method; either a
/// [FunctionExpressionInvocation] or a [MethodInvocation].
///
/// Clients may not extend, implement or mix-in this class.
abstract class InvocationExpression implements Expression {
/// Return the list of arguments to the method.
ArgumentList get argumentList;
/// The expression that identifies the function or method being invoked.
/// For example:
///
/// (o.m)<TArgs>(args); // target will be `o.m`
/// o.m<TArgs>(args); // target will be `m`
///
/// In either case, the [function.staticType] will be the
/// [staticInvokeType] before applying type arguments `TArgs`.
Expression get function;
/// Return the function type of the invocation based on the static type
/// information, or `null` if the AST structure has not been resolved, or if
/// the invoke could not be resolved.
///
/// This will usually be a [FunctionType], but it can also be `dynamic` or
/// `Function`. In the case of interface types that have a `call` method, we
/// store the type of that `call` method here as parameterized.
DartType? get staticInvokeType;
/// Return the type arguments to be applied to the method being invoked, or
/// `null` if no type arguments were provided.
TypeArgumentList? get typeArguments;
/// Return the actual type arguments of the invocation, either explicitly
/// specified in [typeArguments], or inferred.
///
/// If the AST has been resolved, never returns `null`, returns an empty list
/// if the [function] does not have type parameters.
///
/// Return `null` if the AST structure has not been resolved.
List<DartType>? get typeArgumentTypes;
}
/// An is expression.
///
/// isExpression ::=
/// [Expression] 'is' '!'? [TypeAnnotation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class IsExpression implements Expression {
/// Return the expression used to compute the value whose type is being
/// tested.
Expression get expression;
/// Return the is operator.
Token get isOperator;
/// Return the not operator, or `null` if the sense of the test is not
/// negated.
Token? get notOperator;
/// Return the type being tested for.
TypeAnnotation get type;
}
/// A label on either a [LabeledStatement] or a [NamedExpression].
///
/// label ::=
/// [SimpleIdentifier] ':'
///
/// Clients may not extend, implement or mix-in this class.
abstract class Label implements AstNode {
/// Return the colon that separates the label from the statement.
Token get colon;
/// Return the label being associated with the statement.
SimpleIdentifier get label;
}
/// A statement that has a label associated with them.
///
/// labeledStatement ::=
/// [Label]+ [Statement]
///
/// Clients may not extend, implement or mix-in this class.
abstract class LabeledStatement implements Statement {
/// Return the labels being associated with the statement.
NodeList<Label> get labels;
/// Return the statement with which the labels are being associated.
Statement get statement;
}
/// A library directive.
///
/// libraryDirective ::=
/// [Annotation] 'library' [Identifier] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class LibraryDirective implements Directive {
/// Return the token representing the 'library' keyword.
Token get libraryKeyword;
/// Return the name of the library being defined.
LibraryIdentifier get name;
/// Return the semicolon terminating the directive.
Token get semicolon;
}
/// The identifier for a library.
///
/// libraryIdentifier ::=
/// [SimpleIdentifier] ('.' [SimpleIdentifier])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class LibraryIdentifier implements Identifier {
/// Return the components of the identifier.
NodeList<SimpleIdentifier> get components;
}
/// A list literal.
///
/// listLiteral ::=
/// 'const'? [TypeAnnotationList]? '[' elements? ']'
///
/// elements ::=
/// [CollectionElement] (',' [CollectionElement])* ','?
///
/// Clients may not extend, implement or mix-in this class.
abstract class ListLiteral implements TypedLiteral {
/// Return the syntactic elements used to compute the elements of the list.
NodeList<CollectionElement> get elements;
/// Return the left square bracket.
Token get leftBracket;
/// Return the right square bracket.
Token get rightBracket;
}
/// A node that represents a literal expression.
///
/// literal ::=
/// [BooleanLiteral]
/// | [DoubleLiteral]
/// | [IntegerLiteral]
/// | [ListLiteral]
/// | [NullLiteral]
/// | [SetOrMapLiteral]
/// | [StringLiteral]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Literal implements Expression {}
/// A single key/value pair in a map literal.
///
/// mapLiteralEntry ::=
/// [Expression] ':' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class MapLiteralEntry implements CollectionElement {
/// Return the expression computing the key with which the value will be
/// associated.
Expression get key;
/// Return the colon that separates the key from the value.
Token get separator;
/// Return the expression computing the value that will be associated with the
/// key.
Expression get value;
}
/// A method declaration.
///
/// methodDeclaration ::=
/// methodSignature [FunctionBody]
///
/// methodSignature ::=
/// 'external'? ('abstract' | 'static')? [Type]? ('get' | 'set')?
/// methodName [TypeParameterList] [FormalParameterList]
///
/// methodName ::=
/// [SimpleIdentifier]
/// | 'operator' [SimpleIdentifier]
///
/// Prior to the 'extension-methods' experiment, these nodes were always
/// children of a class declaration. When the experiment is enabled, these nodes
/// can also be children of an extension declaration.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MethodDeclaration implements ClassMember {
/// Return the body of the method.
FunctionBody get body;
@override
ExecutableElement? get declaredElement;
/// Return the token for the 'external' keyword, or `null` if the constructor
/// is not external.
Token? get externalKeyword;
/// Return `true` if this method is declared to be an abstract method.
bool get isAbstract;
/// Return `true` if this method declares a getter.
bool get isGetter;
/// Return `true` if this method declares an operator.
bool get isOperator;
/// Return `true` if this method declares a setter.
bool get isSetter;
/// Return `true` if this method is declared to be a static method.
bool get isStatic;
/// Return the token representing the 'abstract' or 'static' keyword, or
/// `null` if neither modifier was specified.
Token? get modifierKeyword;
/// Return the name of the method.
SimpleIdentifier get name;
/// Return the token representing the 'operator' keyword, or `null` if this
/// method does not declare an operator.
Token? get operatorKeyword;
/// Return the parameters associated with the method, or `null` if this method
/// declares a getter.
FormalParameterList? get parameters;
/// Return the token representing the 'get' or 'set' keyword, or `null` if
/// this is a method declaration rather than a property declaration.
Token? get propertyKeyword;
/// Return the return type of the method, or `null` if no return type was
/// declared.
TypeAnnotation? get returnType;
/// Return the type parameters associated with this method, or `null` if this
/// method is not a generic method.
TypeParameterList? get typeParameters;
}
/// The invocation of either a function or a method.
///
/// Invocations of functions resulting from evaluating an expression are
/// represented by [FunctionExpressionInvocation] nodes. Invocations of getters
/// and setters are represented by either [PrefixedIdentifier] or
/// [PropertyAccess] nodes.
///
/// methodInvocation ::=
/// ([Expression] '.')? [SimpleIdentifier] [TypeArgumentList]? [ArgumentList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class MethodInvocation
implements NullShortableExpression, InvocationExpression {
/// Return `true` if this expression is cascaded.
///
/// If it is, then the target of this expression is not stored locally but is
/// stored in the nearest ancestor that is a [CascadeExpression].
bool get isCascaded;
/// Whether this method invocation is null aware (as opposed to non-null).
bool get isNullAware;
/// Return the name of the method being invoked.
SimpleIdentifier get methodName;
/// Return the operator that separates the target from the method name, or
/// `null` if there is no target.
///
/// In an ordinary method invocation this will be period ('.'). In a cascade
/// section this will be the cascade operator ('..').
Token? get operator;
/// Return the expression used to compute the receiver of the invocation.
///
/// If this invocation is not part of a cascade expression, then this is the
/// same as [target]. If this invocation is part of a cascade expression,
/// then the target stored with the cascade expression is returned.
Expression? get realTarget;
/// Return the expression producing the object on which the method is defined,
/// or `null` if there is no target (that is, the target is implicitly `this`)
/// or if this method invocation is part of a cascade expression.
///
/// Use [realTarget] to get the target independent of whether this is part of
/// a cascade expression.
Expression? get target;
}
/// An expression that implicitly makes reference to a method.
///
/// Clients may not extend, implement or mix-in this class.
abstract class MethodReferenceExpression implements AstNode {
/// Return the element associated with the expression based on the static
/// types, or `null` if the AST structure has not been resolved, or there is
/// no meaningful static element to return (e.g. because this is a
/// non-compound assignment expression, or because the method referred to
/// could not be resolved).
MethodElement? get staticElement;
}
/// The declaration of a mixin.
///
/// mixinDeclaration ::=
/// metadata? 'mixin' [SimpleIdentifier] [TypeParameterList]?
/// [OnClause]? [ImplementsClause]? '{' [ClassMember]* '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class MixinDeclaration implements ClassOrMixinDeclaration {
/// Return the token representing the 'mixin' keyword.
Token get mixinKeyword;
/// Return the on clause for the mixin, or `null` if the mixin does not have
/// any superclass constraints.
OnClause? get onClause;
}
/// A node that declares a single name within the scope of a compilation unit.
///
/// Clients may not extend, implement or mix-in this class.
abstract class NamedCompilationUnitMember implements CompilationUnitMember {
/// Return the name of the member being declared.
SimpleIdentifier get name;
}
/// An expression that has a name associated with it. They are used in method
/// invocations when there are named parameters.
///
/// namedExpression ::=
/// [Label] [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class NamedExpression implements Expression {
/// Return the element representing the parameter being named by this
/// expression, or `null` if the AST structure has not been resolved or if
/// there is no parameter with the same name as this expression.
ParameterElement? get element;
/// Return the expression with which the name is associated.
Expression get expression;
/// Return the name associated with the expression.
Label get name;
}
/// A named type, which can optionally include type arguments.
///
/// namedType ::=
/// [Identifier] typeArguments?
///
/// Clients may not extend, implement or mix-in this class.
abstract class NamedType implements TypeAnnotation {
/// Return `true` if this type is a deferred type.
///
/// 15.1 Static Types: A type <i>T</i> is deferred iff it is of the form
/// </i>p.T</i> where <i>p</i> is a deferred prefix.
bool get isDeferred;
/// Return the name of the type.
Identifier get name;
/// Return the type arguments associated with the type, or `null` if there are
/// no type arguments.
TypeArgumentList? get typeArguments;
}
/// A node that represents a directive that impacts the namespace of a library.
///
/// directive ::=
/// [ExportDirective]
/// | [ImportDirective]
///
/// Clients may not extend, implement or mix-in this class.
abstract class NamespaceDirective implements UriBasedDirective {
/// Return the combinators used to control how names are imported or exported.
NodeList<Combinator> get combinators;
/// Return the configurations used to control which library will actually be
/// loaded at run-time.
NodeList<Configuration> get configurations;
/// Return the source that was selected based on the declared variables.
///
/// This will be the source from the first configuration whose condition is
/// true, or the `[uriSource]` if either there are no configurations or if
/// there are no configurations whose condition is true.
Source? get selectedSource;
/// Return the content of the URI that was selected based on the declared
/// variables.
///
/// This will be the URI from the first configuration whose condition is
/// true, or the `[uriContent]` if either there are no configurations or if
/// there are no configurations whose condition is true.
String? get selectedUriContent;
/// Return the semicolon terminating the directive.
Token get semicolon;
@override
LibraryElement? get uriElement;
}
/// The "native" clause in an class declaration.
///
/// nativeClause ::=
/// 'native' [StringLiteral]
///
/// Clients may not extend, implement or mix-in this class.
abstract class NativeClause implements AstNode {
/// Return the name of the native object that implements the class.
StringLiteral? get name;
/// Return the token representing the 'native' keyword.
Token get nativeKeyword;
}
/// A function body that consists of a native keyword followed by a string
/// literal.
///
/// nativeFunctionBody ::=
/// 'native' [SimpleStringLiteral] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class NativeFunctionBody implements FunctionBody {
/// Return the token representing 'native' that marks the start of the
/// function body.
Token get nativeKeyword;
/// Return the token representing the semicolon that marks the end of the
/// function body.
Token get semicolon;
/// Return the string literal representing the string after the 'native'
/// token.
StringLiteral? get stringLiteral;
}
/// A list of AST nodes that have a common parent.
///
/// Clients may not extend, implement or mix-in this class.
abstract class NodeList<E extends AstNode> implements List<E> {
/// Return the first token included in this node list's source range, or
/// `null` if the list is empty.
Token? get beginToken;
/// Return the last token included in this node list's source range, or `null`
/// if the list is empty.
Token? get endToken;
/// Return the node that is the parent of each of the elements in the list.
AstNode get owner;
/// Return the node at the given [index] in the list or throw a [RangeError]
/// if [index] is out of bounds.
@override
E operator [](int index);
/// Use the given [visitor] to visit each of the nodes in this list.
void accept(AstVisitor visitor);
}
/// A formal parameter that is required (is not optional).
///
/// normalFormalParameter ::=
/// [FunctionTypedFormalParameter]
/// | [FieldFormalParameter]
/// | [SimpleFormalParameter]
///
/// Clients may not extend, implement or mix-in this class.
abstract class NormalFormalParameter implements FormalParameter {
/// Return the documentation comment associated with this parameter, or `null`
/// if this parameter does not have a documentation comment associated with
/// it.
Comment? get documentationComment;
/// Return a list containing the comment and annotations associated with this
/// parameter, sorted in lexical order.
List<AstNode> get sortedCommentAndAnnotations;
}
/// A null literal expression.
///
/// nullLiteral ::=
/// 'null'
///
/// Clients may not extend, implement or mix-in this class.
abstract class NullLiteral implements Literal {
/// Return the token representing the literal.
Token get literal;
}
/// Abstract interface for expressions that may participate in null-shorting.
abstract class NullShortableExpression implements Expression {
/// Returns the expression that terminates any null shorting that might occur
/// in this expression. This may be called regardless of whether this
/// expression is itself null-aware.
///
/// For example, the statement `a?.b[c] = d;` contains the following
/// null-shortable subexpressions:
/// - `a?.b`
/// - `a?.b[c]`
/// - `a?.b[c] = d`
///
/// Calling [nullShortingTermination] on any of these subexpressions yields
/// the expression `a?.b[c] = d`, indicating that the null-shorting induced by
/// the `?.` causes the rest of the subexpression `a?.b[c] = d` to be skipped.
Expression get nullShortingTermination;
}
/// The "on" clause in a mixin declaration.
///
/// onClause ::=
/// 'on' [TypeName] (',' [TypeName])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class OnClause implements AstNode {
/// Return the token representing the 'on' keyword.
Token get onKeyword;
/// Return the list of the classes are superclass constraints for the mixin.
NodeList<TypeName> get superclassConstraints;
}
/// A parenthesized expression.
///
/// parenthesizedExpression ::=
/// '(' [Expression] ')'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ParenthesizedExpression implements Expression {
/// Return the expression within the parentheses.
Expression get expression;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
}
/// A part directive.
///
/// partDirective ::=
/// [Annotation] 'part' [StringLiteral] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class PartDirective implements UriBasedDirective {
/// Return the token representing the 'part' keyword.
Token get partKeyword;
/// Return the semicolon terminating the directive.
Token get semicolon;
}
/// A part-of directive.
///
/// partOfDirective ::=
/// [Annotation] 'part' 'of' [Identifier] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class PartOfDirective implements Directive {
/// Return the name of the library that the containing compilation unit is
/// part of.
LibraryIdentifier? get libraryName;
/// Return the token representing the 'of' keyword.
Token get ofKeyword;
/// Return the token representing the 'part' keyword.
Token get partKeyword;
/// Return the semicolon terminating the directive.
Token get semicolon;
/// Return the URI of the library that the containing compilation unit is part
/// of, or `null` if no URI was given (typically because a library name was
/// provided).
StringLiteral? get uri;
}
/// A postfix unary expression.
///
/// postfixExpression ::=
/// [Expression] [Token]
///
/// Clients may not extend, implement or mix-in this class.
abstract class PostfixExpression
implements
Expression,
NullShortableExpression,
MethodReferenceExpression,
CompoundAssignmentExpression {
/// Return the expression computing the operand for the operator.
Expression get operand;
/// Return the postfix operator being applied to the operand.
Token get operator;
}
/// An identifier that is prefixed or an access to an object property where the
/// target of the property access is a simple identifier.
///
/// prefixedIdentifier ::=
/// [SimpleIdentifier] '.' [SimpleIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class PrefixedIdentifier implements Identifier {
/// Return the identifier being prefixed.
SimpleIdentifier get identifier;
/// Return `true` if this type is a deferred type. If the AST structure has
/// not been resolved, then return `false`.
///
/// 15.1 Static Types: A type <i>T</i> is deferred iff it is of the form
/// </i>p.T</i> where <i>p</i> is a deferred prefix.
bool get isDeferred;
/// Return the period used to separate the prefix from the identifier.
Token get period;
/// Return the prefix associated with the library in which the identifier is
/// defined.
SimpleIdentifier get prefix;
}
/// A prefix unary expression.
///
/// prefixExpression ::=
/// [Token] [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class PrefixExpression
implements
Expression,
NullShortableExpression,
MethodReferenceExpression,
CompoundAssignmentExpression {
/// Return the expression computing the operand for the operator.
Expression get operand;
/// Return the prefix operator being applied to the operand.
Token get operator;
}
/// The access of a property of an object.
///
/// Note, however, that accesses to properties of objects can also be
/// represented as [PrefixedIdentifier] nodes in cases where the target is also
/// a simple identifier.
///
/// propertyAccess ::=
/// [Expression] '.' [SimpleIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class PropertyAccess implements NullShortableExpression {
/// Return `true` if this expression is cascaded.
///
/// If it is, then the target of this expression is not stored locally but is
/// stored in the nearest ancestor that is a [CascadeExpression].
bool get isCascaded;
/// Whether this property access is null aware (as opposed to non-null).
bool get isNullAware;
/// Return the property access operator.
Token get operator;
/// Return the name of the property being accessed.
SimpleIdentifier get propertyName;
/// Return the expression used to compute the receiver of the invocation.
///
/// If this invocation is not part of a cascade expression, then this is the
/// same as [target]. If this invocation is part of a cascade expression,
/// then the target stored with the cascade expression is returned.
Expression get realTarget;
/// Return the expression computing the object defining the property being
/// accessed, or `null` if this property access is part of a cascade
/// expression.
///
/// Use [realTarget] to get the target independent of whether this is part of
/// a cascade expression.
Expression? get target;
}
/// The invocation of a constructor in the same class from within a
/// constructor's initialization list.
///
/// redirectingConstructorInvocation ::=
/// 'this' ('.' identifier)? arguments
///
/// Clients may not extend, implement or mix-in this class.
abstract class RedirectingConstructorInvocation
implements ConstructorInitializer, ConstructorReferenceNode {
/// Return the list of arguments to the constructor.
ArgumentList get argumentList;
/// Return the name of the constructor that is being invoked, or `null` if the
/// unnamed constructor is being invoked.
SimpleIdentifier? get constructorName;
/// Return the token for the period before the name of the constructor that is
/// being invoked, or `null` if the unnamed constructor is being invoked.
Token? get period;
/// Return the token for the 'this' keyword.
Token get thisKeyword;
}
/// A rethrow expression.
///
/// rethrowExpression ::=
/// 'rethrow'
///
/// Clients may not extend, implement or mix-in this class.
abstract class RethrowExpression implements Expression {
/// Return the token representing the 'rethrow' keyword.
Token get rethrowKeyword;
}
/// A return statement.
///
/// returnStatement ::=
/// 'return' [Expression]? ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ReturnStatement implements Statement {
/// Return the expression computing the value to be returned, or `null` if no
/// explicit value was provided.
Expression? get expression;
/// Return the token representing the 'return' keyword.
Token get returnKeyword;
/// Return the semicolon terminating the statement.
Token get semicolon;
}
/// A script tag that can optionally occur at the beginning of a compilation
/// unit.
///
/// scriptTag ::=
/// '#!' (~NEWLINE)* NEWLINE
///
/// Clients may not extend, implement or mix-in this class.
abstract class ScriptTag implements AstNode {
/// Return the token representing this script tag.
Token get scriptTag;
}
/// A set or map literal.
///
/// setOrMapLiteral ::=
/// 'const'? [TypeArgumentList]? '{' elements? '}'
///
/// elements ::=
/// [CollectionElement] ( ',' [CollectionElement] )* ','?
///
/// This is the class that is used to represent either a map or set literal when
/// either the 'control-flow-collections' or 'spread-collections' experiments
/// are enabled. If neither of those experiments are enabled, then `MapLiteral`
/// will be used to represent a map literal and `SetLiteral` will be used for
/// set literals.
///
/// Clients may not extend, implement or mix-in this class.
abstract class SetOrMapLiteral implements TypedLiteral {
/// Return the syntactic elements used to compute the elements of the set or
/// map.
NodeList<CollectionElement> get elements;
/// Return `true` if this literal represents a map literal.
///
/// This getter will always return `false` if [isSet] returns `true`.
///
/// However, this getter is _not_ the inverse of [isSet]. It is possible for
/// both getters to return `false` if
///
/// - the AST has not been resolved (because determining the kind of the
/// literal is done during resolution),
/// - the literal is ambiguous (contains one or more spread elements and none
/// of those elements can be used to determine the kind of the literal), or
/// - the literal is invalid because it contains both expressions (for sets)
/// and map entries (for maps).
///
/// In both of the latter two cases there will be compilation errors
/// associated with the literal.
bool get isMap;
/// Return `true` if this literal represents a set literal.
///
/// This getter will always return `false` if [isMap] returns `true`.
///
/// However, this getter is _not_ the inverse of [isMap]. It is possible for
/// both getters to return `false` if
///
/// - the AST has not been resolved (because determining the kind of the
/// literal is done during resolution),
/// - the literal is ambiguous (contains one or more spread elements and none
/// of those elements can be used to determine the kind of the literal), or
/// - the literal is invalid because it contains both expressions (for sets)
/// and map entries (for maps).
///
/// In both of the latter two cases there will be compilation errors
/// associated with the literal.
bool get isSet;
/// Return the left curly bracket.
Token get leftBracket;
/// Return the right curly bracket.
Token get rightBracket;
}
/// A combinator that restricts the names being imported to those in a given list.
///
/// showCombinator ::=
/// 'show' [SimpleIdentifier] (',' [SimpleIdentifier])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class ShowCombinator implements Combinator {
/// Return the list of names from the library that are made visible by this
/// combinator.
NodeList<SimpleIdentifier> get shownNames;
}
/// A simple formal parameter.
///
/// simpleFormalParameter ::=
/// ('final' [TypeAnnotation] | 'var' | [TypeAnnotation])? [SimpleIdentifier]
///
/// Clients may not extend, implement or mix-in this class.
abstract class SimpleFormalParameter implements NormalFormalParameter {
/// Return the token representing either the 'final', 'const' or 'var'
/// keyword, or `null` if no keyword was used.
Token? get keyword;
/// Return the declared type of the parameter, or `null` if the parameter does
/// not have a declared type.
TypeAnnotation? get type;
}
/// A simple identifier.
///
/// simpleIdentifier ::=
/// initialCharacter internalCharacter*
///
/// initialCharacter ::= '_' | '$' | letter
///
/// internalCharacter ::= '_' | '$' | letter | digit
///
/// Clients may not extend, implement or mix-in this class.
abstract class SimpleIdentifier implements Identifier {
/// Return `true` if this identifier is the "name" part of a prefixed
/// identifier or a method invocation.
bool get isQualified;
/// If the identifier is a tear-off, return the inferred type arguments
/// applied to the function type of the element to produce its `[staticType]`.
///
/// Return an empty list if the function type does not have type parameters.
///
/// Return an empty list if the context type has type parameters.
///
/// Return `null` if not a tear-off.
///
/// Return `null` if the AST structure has not been resolved.
List<DartType>? get tearOffTypeArgumentTypes;
/// Return the token representing the identifier.
Token get token;
/// Return `true` if this identifier is the name being declared in a
/// declaration.
// TODO(brianwilkerson) Convert this to a getter.
bool inDeclarationContext();
/// Return `true` if this expression is computing a right-hand value.
///
/// Note that [inGetterContext] and [inSetterContext] are not opposites, nor
/// are they mutually exclusive. In other words, it is possible for both
/// methods to return `true` when invoked on the same node.
// TODO(brianwilkerson) Convert this to a getter.
bool inGetterContext();
/// Return `true` if this expression is computing a left-hand value.
///
/// Note that [inGetterContext] and [inSetterContext] are not opposites, nor
/// are they mutually exclusive. In other words, it is possible for both
/// methods to return `true` when invoked on the same node.
// TODO(brianwilkerson) Convert this to a getter.
bool inSetterContext();
}
/// A string literal expression that does not contain any interpolations.
///
/// simpleStringLiteral ::=
/// rawStringLiteral
/// | basicStringLiteral
///
/// rawStringLiteral ::=
/// 'r' basicStringLiteral
///
/// basicStringLiteral ::=
/// multiLineStringLiteral
/// | singleLineStringLiteral
///
/// multiLineStringLiteral ::=
/// "'''" characters "'''"
/// | '"""' characters '"""'
///
/// singleLineStringLiteral ::=
/// "'" characters "'"
/// | '"' characters '"'
///
/// Clients may not extend, implement or mix-in this class.
abstract class SimpleStringLiteral implements SingleStringLiteral {
/// Return the token representing the literal.
Token get literal;
/// Return the value of the literal.
String get value;
}
/// A single string literal expression.
///
/// singleStringLiteral ::=
/// [SimpleStringLiteral]
/// | [StringInterpolation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class SingleStringLiteral implements StringLiteral {
/// Return the offset of the after-last contents character.
int get contentsEnd;
/// Return the offset of the first contents character.
///
/// If the string is multiline, then leading whitespaces are skipped.
int get contentsOffset;
/// Return `true` if this string literal is a multi-line string.
bool get isMultiline;
/// Return `true` if this string literal is a raw string.
bool get isRaw;
/// Return `true` if this string literal uses single quotes (' or '''), or
/// `false` if this string literal uses double quotes (" or """).
bool get isSingleQuoted;
}
/// A spread element.
///
/// spreadElement:
/// ( '...' | '...?' ) [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class SpreadElement implements CollectionElement {
/// The expression used to compute the collection being spread.
Expression get expression;
/// Whether this is a null-aware spread, as opposed to a non-null spread.
bool get isNullAware;
/// The spread operator, either '...' or '...?'.
Token get spreadOperator;
}
/// A node that represents a statement.
///
/// statement ::=
/// [Block]
/// | [VariableDeclarationStatement]
/// | [ForStatement]
/// | [ForEachStatement]
/// | [WhileStatement]
/// | [DoStatement]
/// | [SwitchStatement]
/// | [IfStatement]
/// | [TryStatement]
/// | [BreakStatement]
/// | [ContinueStatement]
/// | [ReturnStatement]
/// | [ExpressionStatement]
/// | [FunctionDeclarationStatement]
///
/// Clients may not extend, implement or mix-in this class.
abstract class Statement implements AstNode {
/// If this is a labeled statement, return the unlabeled portion of the
/// statement, otherwise return the statement itself.
Statement get unlabeled;
}
/// A string interpolation literal.
///
/// stringInterpolation ::=
/// ''' [InterpolationElement]* '''
/// | '"' [InterpolationElement]* '"'
///
/// Clients may not extend, implement or mix-in this class.
abstract class StringInterpolation implements SingleStringLiteral {
/// Return the elements that will be composed to produce the resulting string.
/// The list includes [firstString] and [lastString].
NodeList<InterpolationElement> get elements;
/// Return the first element in this interpolation, which is always a string.
/// The string might be empty if there is no text before the first
/// interpolation expression (such as in `'$foo bar'`).
InterpolationString get firstString;
/// Return the last element in this interpolation, which is always a string.
/// The string might be empty if there is no text after the last
/// interpolation expression (such as in `'foo $bar'`).
InterpolationString get lastString;
}
/// A string literal expression.
///
/// stringLiteral ::=
/// [SimpleStringLiteral]
/// | [AdjacentStrings]
/// | [StringInterpolation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class StringLiteral implements Literal {
/// Return the value of the string literal, or `null` if the string is not a
/// constant string without any string interpolation.
String? get stringValue;
}
/// The invocation of a superclass' constructor from within a constructor's
/// initialization list.
///
/// superInvocation ::=
/// 'super' ('.' [SimpleIdentifier])? [ArgumentList]
///
/// Clients may not extend, implement or mix-in this class.
abstract class SuperConstructorInvocation
implements ConstructorInitializer, ConstructorReferenceNode {
/// Return the list of arguments to the constructor.
ArgumentList get argumentList;
/// Return the name of the constructor that is being invoked, or `null` if the
/// unnamed constructor is being invoked.
SimpleIdentifier? get constructorName;
/// Return the token for the period before the name of the constructor that is
/// being invoked, or `null` if the unnamed constructor is being invoked.
Token? get period;
/// Return the token for the 'super' keyword.
Token get superKeyword;
}
/// A super expression.
///
/// superExpression ::=
/// 'super'
///
/// Clients may not extend, implement or mix-in this class.
abstract class SuperExpression implements Expression {
/// Return the token representing the 'super' keyword.
Token get superKeyword;
}
/// A case in a switch statement.
///
/// switchCase ::=
/// [SimpleIdentifier]* 'case' [Expression] ':' [Statement]*
///
/// Clients may not extend, implement or mix-in this class.
abstract class SwitchCase implements SwitchMember {
/// Return the expression controlling whether the statements will be executed.
Expression get expression;
}
/// The default case in a switch statement.
///
/// switchDefault ::=
/// [SimpleIdentifier]* 'default' ':' [Statement]*
///
/// Clients may not extend, implement or mix-in this class.
abstract class SwitchDefault implements SwitchMember {}
/// An element within a switch statement.
///
/// switchMember ::=
/// switchCase
/// | switchDefault
///
/// Clients may not extend, implement or mix-in this class.
abstract class SwitchMember implements AstNode {
/// Return the colon separating the keyword or the expression from the
/// statements.
Token get colon;
/// Return the token representing the 'case' or 'default' keyword.
Token get keyword;
/// Return the labels associated with the switch member.
NodeList<Label> get labels;
/// Return the statements that will be executed if this switch member is
/// selected.
NodeList<Statement> get statements;
}
/// A switch statement.
///
/// switchStatement ::=
/// 'switch' '(' [Expression] ')' '{' [SwitchCase]* [SwitchDefault]? '}'
///
/// Clients may not extend, implement or mix-in this class.
abstract class SwitchStatement implements Statement {
/// Return the expression used to determine which of the switch members will
/// be selected.
Expression get expression;
/// Return the left curly bracket.
Token get leftBracket;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the switch members that can be selected by the expression.
NodeList<SwitchMember> get members;
/// Return the right curly bracket.
Token get rightBracket;
/// Return the right parenthesis.
Token get rightParenthesis;
/// Return the token representing the 'switch' keyword.
Token get switchKeyword;
}
/// A symbol literal expression.
///
/// symbolLiteral ::=
/// '#' (operator | (identifier ('.' identifier)*))
///
/// Clients may not extend, implement or mix-in this class.
abstract class SymbolLiteral implements Literal {
/// Return the components of the literal.
List<Token> get components;
/// Return the token introducing the literal.
Token get poundSign;
}
/// A this expression.
///
/// thisExpression ::=
/// 'this'
///
/// Clients may not extend, implement or mix-in this class.
abstract class ThisExpression implements Expression {
/// Return the token representing the 'this' keyword.
Token get thisKeyword;
}
/// A throw expression.
///
/// throwExpression ::=
/// 'throw' [Expression]
///
/// Clients may not extend, implement or mix-in this class.
abstract class ThrowExpression implements Expression {
/// Return the expression computing the exception to be thrown.
Expression get expression;
/// Return the token representing the 'throw' keyword.
Token get throwKeyword;
}
/// The declaration of one or more top-level variables of the same type.
///
/// topLevelVariableDeclaration ::=
/// ('final' | 'const') <type>? <staticFinalDeclarationList> ';'
/// | 'late' 'final' <type>? <initializedIdentifierList> ';'
/// | 'late'? <varOrType> <initializedIdentifierList> ';'
/// | 'external' <finalVarOrType> <identifierList> ';'
///
/// (Note: there is no <topLevelVariableDeclaration> production in the grammar;
/// this is a subset of the grammar production <topLevelDeclaration>, which
/// encompasses everything that can appear inside a Dart file after part
/// directives).
///
/// Clients may not extend, implement or mix-in this class.
abstract class TopLevelVariableDeclaration implements CompilationUnitMember {
/// The `external` keyword, or `null` if the keyword was not used.
Token? get externalKeyword;
/// Return the semicolon terminating the declaration.
Token get semicolon;
/// Return the top-level variables being declared.
VariableDeclarationList get variables;
}
/// A try statement.
///
/// tryStatement ::=
/// 'try' [Block] ([CatchClause]+ finallyClause? | finallyClause)
///
/// finallyClause ::=
/// 'finally' [Block]
///
/// Clients may not extend, implement or mix-in this class.
abstract class TryStatement implements Statement {
/// Return the body of the statement.
Block get body;
/// Return the catch clauses contained in the try statement.
NodeList<CatchClause> get catchClauses;
/// Return the finally block contained in the try statement, or `null` if the
/// statement does not contain a finally clause.
Block? get finallyBlock;
/// Return the token representing the 'finally' keyword, or `null` if the
/// statement does not contain a finally clause.
Token? get finallyKeyword;
/// Return the token representing the 'try' keyword.
Token get tryKeyword;
}
/// The declaration of a type alias.
///
/// typeAlias ::=
/// 'typedef' typeAliasBody
///
/// typeAliasBody ::=
/// classTypeAlias
/// | functionTypeAlias
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeAlias implements NamedCompilationUnitMember {
@override
SimpleIdentifier get name;
/// Return the semicolon terminating the declaration.
Token get semicolon;
/// Return the token representing the 'typedef' keyword.
Token get typedefKeyword;
}
/// A type annotation.
///
/// type ::=
/// [NamedType]
/// | [GenericFunctionType]
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeAnnotation implements AstNode {
/// The question mark indicating that the type is nullable, or `null` if there
/// is no question mark.
Token? get question;
/// Return the type being named, or `null` if the AST structure has not been
/// resolved.
DartType? get type;
}
/// A list of type arguments.
///
/// typeArguments ::=
/// '<' typeName (',' typeName)* '>'
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeArgumentList implements AstNode {
/// Return the type arguments associated with the type.
NodeList<TypeAnnotation> get arguments;
/// Return the left bracket.
Token get leftBracket;
/// Return the right bracket.
Token get rightBracket;
}
/// A literal that has a type associated with it.
///
/// typedLiteral ::=
/// [ListLiteral]
/// | [SetOrMapLiteral]
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypedLiteral implements Literal {
/// Return the token representing the 'const' keyword, or `null` if the
/// literal is not a constant.
Token? get constKeyword;
/// Return `true` if this literal is a constant expression, either because the
/// keyword `const` was explicitly provided or because no keyword was provided
/// and this expression is in a constant context.
bool get isConst;
/// Return the type argument associated with this literal, or `null` if no
/// type arguments were declared.
TypeArgumentList? get typeArguments;
}
/// An expression representing a type, e.g. the expression `int` in
/// `var x = int;`.
///
/// Objects of this type are not produced directly by the parser (because the
/// parser cannot tell whether an identifier refers to a type); they are
/// produced at resolution time.
///
/// The `.staticType` getter returns the type of the expression (which will
/// always be the type `Type`). To see the type represented by the type literal
/// use `.typeName.type`.
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeLiteral implements Expression {
/// The type represented by this literal.
TypeName get typeName;
}
/// The name of a type, which can optionally include type arguments.
///
/// typeName ::=
/// [Identifier] typeArguments?
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeName implements NamedType {}
/// A type parameter.
///
/// typeParameter ::=
/// [SimpleIdentifier] ('extends' [TypeAnnotation])?
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeParameter implements Declaration {
/// Return the upper bound for legal arguments, or `null` if there is no
/// explicit upper bound.
TypeAnnotation? get bound;
@override
TypeParameterElement? get declaredElement;
/// Return the token representing the 'extends' keyword, or `null` if there is
/// no explicit upper bound.
Token? get extendsKeyword;
/// Return the name of the type parameter.
SimpleIdentifier get name;
}
/// Type parameters within a declaration.
///
/// typeParameterList ::=
/// '<' [TypeParameter] (',' [TypeParameter])* '>'
///
/// Clients may not extend, implement or mix-in this class.
abstract class TypeParameterList implements AstNode {
/// Return the left angle bracket.
Token get leftBracket;
/// Return the right angle bracket.
Token get rightBracket;
/// Return the type parameters for the type.
NodeList<TypeParameter> get typeParameters;
}
/// A directive that references a URI.
///
/// uriBasedDirective ::=
/// [ExportDirective]
/// | [ImportDirective]
/// | [PartDirective]
///
/// Clients may not extend, implement or mix-in this class.
abstract class UriBasedDirective implements Directive {
/// Return the URI referenced by this directive.
StringLiteral get uri;
/// Return the content of the [uri], or `null` if the AST structure has not
/// been resolved, or if the [uri] has a string interpolation.
String? get uriContent;
/// Return the element associated with the [uri] of this directive, or `null`
/// if the AST structure has not been resolved or if the URI could not be
/// resolved.
///
/// Examples of the latter case include a directive that contains an invalid
/// URL or a URL that does not exist.
Element? get uriElement;
/// Return the source to which the [uri] was resolved.
Source? get uriSource;
}
/// An identifier that has an initial value associated with it.
///
/// Instances of this class are always children of the class
/// [VariableDeclarationList].
///
/// variableDeclaration ::=
/// [SimpleIdentifier] ('=' [Expression])?
///
/// Clients may not extend, implement or mix-in this class.
// TODO(paulberry): the grammar does not allow metadata to be associated with a
// VariableDeclaration, and currently we don't record comments for it either.
// Consider changing the class hierarchy so that [VariableDeclaration] does not
// extend [Declaration].
abstract class VariableDeclaration implements Declaration {
@override
VariableElement? get declaredElement;
/// Return the equal sign separating the variable name from the initial value,
/// or `null` if the initial value was not specified.
Token? get equals;
/// Return the expression used to compute the initial value for the variable,
/// or `null` if the initial value was not specified.
Expression? get initializer;
/// 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 was declared with the 'late' modifier.
bool get isLate;
/// Return the name of the variable being declared.
SimpleIdentifier get name;
}
/// The declaration of one or more variables of the same type.
///
/// variableDeclarationList ::=
/// finalConstVarOrType [VariableDeclaration] (',' [VariableDeclaration])*
///
/// finalConstVarOrType ::=
/// 'final' 'late'? [TypeAnnotation]?
/// | 'const' [TypeAnnotation]?
/// | 'var'
/// | 'late'? [TypeAnnotation]
///
/// Clients may not extend, implement or mix-in this class.
abstract class VariableDeclarationList implements AnnotatedNode {
/// Return `true` if the variables in this list were declared with the 'const'
/// modifier.
bool get isConst;
/// Return `true` if the variables in this list were declared with the 'final'
/// modifier.
///
/// Variables that are declared with the 'const' modifier will return `false`
/// even though they are implicitly final. (In other words, this is a
/// syntactic check rather than a semantic check.)
bool get isFinal;
/// Return `true` if the variables in this list were declared with the 'late'
/// modifier.
bool get isLate;
/// Return the token representing the 'final', 'const' or 'var' keyword, or
/// `null` if no keyword was included.
Token? get keyword;
/// Return the token representing the 'late' keyword, or `null` if the late
/// modifier was not included.
Token? get lateKeyword;
/// Return the type of the variables being declared, or `null` if no type was
/// provided.
TypeAnnotation? get type;
/// Return a list containing the individual variables being declared.
NodeList<VariableDeclaration> get variables;
}
/// A list of variables that are being declared in a context where a statement
/// is required.
///
/// variableDeclarationStatement ::=
/// [VariableDeclarationList] ';'
///
/// Clients may not extend, implement or mix-in this class.
abstract class VariableDeclarationStatement implements Statement {
/// Return the semicolon terminating the statement.
Token get semicolon;
/// Return the variables being declared.
VariableDeclarationList get variables;
}
/// A while statement.
///
/// whileStatement ::=
/// 'while' '(' [Expression] ')' [Statement]
///
/// Clients may not extend, implement or mix-in this class.
abstract class WhileStatement implements Statement {
/// Return the body of the loop.
Statement get body;
/// Return the expression used to determine whether to execute the body of the
/// loop.
Expression get condition;
/// Return the left parenthesis.
Token get leftParenthesis;
/// Return the right parenthesis.
Token get rightParenthesis;
/// Return the token representing the 'while' keyword.
Token get whileKeyword;
}
/// The with clause in a class declaration.
///
/// withClause ::=
/// 'with' [TypeName] (',' [TypeName])*
///
/// Clients may not extend, implement or mix-in this class.
abstract class WithClause implements AstNode {
/// Return the names of the mixins that were specified.
NodeList<TypeName> get mixinTypes;
/// Return the token representing the 'with' keyword.
Token get withKeyword;
}
/// A yield statement.
///
/// yieldStatement ::=
/// 'yield' '*'? [Expression] ‘;’
///
/// Clients may not extend, implement or mix-in this class.
abstract class YieldStatement implements Statement {
/// Return the expression whose value will be yielded.
Expression get expression;
/// Return the semicolon following the expression.
Token get semicolon;
/// Return the star optionally following the 'yield' keyword.
Token? get star;
/// Return the 'yield' keyword.
Token get yieldKeyword;
}