pkg/nnbd_migration/lib/instrumentation.dart - sdk.git - Git at Google

 // Copyright (c) 2019, 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.

 import 'package:analyzer/dart/ast/ast.dart';
 import 'package:analyzer/dart/element/element.dart';
 import 'package:analyzer/dart/element/type.dart';
 import 'package:analyzer/src/generated/source.dart';
 import 'package:nnbd_migration/src/edit_plan.dart';
 import 'package:nnbd_migration/src/hint_action.dart';

 /// Data structure used by the nullability migration engine to refer to a
 /// specific location in source code.
 class CodeReference {
   final String path;

   final int line;

   final int column;

   final int offset;

   /// Name of the enclosing function, or `null` if not known.
   String? function;

   CodeReference(this.path, this.offset, this.line, this.column, this.function);

   /// Creates a [CodeReference] pointing to the given [node].
   factory CodeReference.fromAstNode(AstNode node) {
     var compilationUnit = node.thisOrAncestorOfType<CompilationUnit>()!;
     var source = compilationUnit.declaredElement!.source;
     var location = compilationUnit.lineInfo!.getLocation(node.offset);
     return CodeReference(source.fullName, node.offset, location.lineNumber,
         location.columnNumber, _computeEnclosingName(node));
   }

   factory CodeReference.fromElement(
       Element element, LineInfo Function(String) getLineInfo) {
     var path = element.source!.fullName;
     var offset = element.nameOffset;
     var location = getLineInfo(path).getLocation(offset);
     return CodeReference(path, offset, location.lineNumber,
         location.columnNumber, _computeElementFullName(element));
   }

   /// Gets a short description of this code reference (using the last component
   /// of the path rather than the full path)
   String get shortName => '$shortPath:$line:$column';

   /// Gets the last component of the path part of this code reference.
   String get shortPath {
     var pathAsUri = Uri.file(path);
     return pathAsUri.pathSegments.last;
   }

   @override
   String toString() {
     var pathAsUri = Uri.file(path);
     return '${function ?? 'unknown'} ($pathAsUri:$line:$column)';
   }

   static String? _computeElementFullName(Element? element) {
     List<String> parts = [];
     while (element != null) {
       var elementName = _computeElementName(element);
       if (elementName != null) {
         parts.add(elementName);
       }
       element = element.enclosingElement;
     }
     if (parts.isEmpty) return null;
     return parts.reversed.join('.');
   }

   static String? _computeElementName(Element element) {
     if (element is CompilationUnitElement || element is LibraryElement) {
       return null;
     }
     return element.name;
   }

   static String? _computeEnclosingName(AstNode? node) {
     List<String?> parts = [];
     while (node != null) {
       var nodeName = _computeNodeDeclarationName(node);
       if (nodeName != null) {
         parts.add(nodeName);
       } else if (parts.isEmpty && node is VariableDeclarationList) {
         parts.add(node.variables.first.declaredElement!.name);
       }
       node = node.parent;
     }
     if (parts.isEmpty) return null;
     return parts.reversed.join('.');
   }

   static String? _computeNodeDeclarationName(AstNode node) {
     if (node is ExtensionDeclaration) {
       return node.declaredElement?.name ?? '<unnamed extension>';
     } else if (node is Declaration) {
       var name = node.declaredElement?.name;
       return name == '' ? '<unnamed>' : name;
     } else {
       return null;
     }
   }
 }

 /// Information exposed to the migration client about the set of nullability
 /// nodes decorating a type in the program being migrated.
 abstract class DecoratedTypeInfo {
   /// Information about the graph node associated with the decision of whether
   /// or not to make this type into a nullable type.
   NullabilityNodeInfo? get node;

   /// If [type] is a function type, information about the set of nullability
   /// nodes decorating the type's return type.
   DecoratedTypeInfo? get returnType;

   /// The original (pre-migration) type that is being migrated.
   DartType? get type;

   /// If [type] is a function type, looks up information about the set of
   /// nullability nodes decorating one of the type's named parameter types.
   DecoratedTypeInfo? namedParameter(String name);

   /// If [type] is a function type, looks up information about the set of
   /// nullability nodes decorating one of the type's positional parameter types.
   /// (This could be an optional or a required positional parameter).
   DecoratedTypeInfo? positionalParameter(int i);

   /// If [type] is an interface type, looks up information about the set of
   /// nullability nodes decorating one of the type's type arguments.
   DecoratedTypeInfo? typeArgument(int i);
 }

 /// Information about a propagation step that occurred during downstream
 /// propagation.
 abstract class DownstreamPropagationStepInfo implements PropagationStepInfo {
   DownstreamPropagationStepInfo? get principalCause;

   /// The node whose nullability was changed.
   ///
   /// Any propagation step that took effect should have a non-null value here.
   /// Propagation steps that are pending but have not taken effect yet, or that
   /// never had an effect (e.g. because an edge was not triggered) will have a
   /// `null` value for this field.
   NullabilityNodeInfo? get targetNode;
 }

 /// Information exposed to the migration client about an edge in the nullability
 /// graph.
 ///
 /// A graph edge represents a dependency relationship between two types being
 /// migrated, suggesting that if one type (the source) is made nullable, it may
 /// be desirable to make the other type (the destination) nullable as well.
 abstract class EdgeInfo implements FixReasonInfo {
   /// User-friendly description of the edge, or `null` if not known.
   String get description;

   /// Information about the graph node that this edge "points to".
   NullabilityNodeInfo get destinationNode;

   /// The set of "guard nodes" for this edge.  Guard nodes are graph nodes whose
   /// nullability determines whether it is important to satisfy a graph edge.
   /// If at least one of an edge's guards is non-nullable, then it is not
   /// important to satisfy the graph edge.  (Typically this is because the code
   /// that led to the graph edge being created is only reachable if the guards
   /// are all nullable).
   Iterable<NullabilityNodeInfo?> get guards;

   /// A boolean indicating whether the graph edge is a "hard" edge.  Hard edges
   /// are associated with unconditional control flow, and thus allow information
   /// about non-nullability to be propagated "upstream" through the nullability
   /// graph.
   bool get isHard;

   /// A boolean indicating whether the graph edge is "satisfied".  At its heart,
   /// the nullability propagation algorithm is an effort to satisfy graph edges
   /// in a way that corresponds to the user's intent.  A graph edge is
   /// considered satisfied if any of the following is true:
   /// - Its [sourceNode] is non-nullable.
   /// - One of its [guards] is non-nullable.
   /// - Its [destinationNode] is nullable.
   bool get isSatisfied;

   /// Indicates whether all the upstream nodes of this edge are nullable (and
   /// thus downstream nullability propagation should try to make the destination
   /// node nullable, if possible).
   bool get isTriggered;

   /// A boolean indicating whether the graph edge is a "union" edge.  Union
   /// edges are edges for which the nullability propagation algorithm tries to
   /// ensure that both the [sourceNode] and the [destinationNode] have the
   /// same nullability.  Typically these are associated with situations where
   /// Dart language semantics require two types to be the same type (e.g. a type
   /// formal bound on a generic function type in a base class, and the
   /// corresponding type formal bound on a generic function type in an
   /// overriding class).
   ///
   /// The [isHard] property is always true for union edges.
   bool get isUnion;

   /// Indicates whether the downstream node of this edge is non-nullable and the
   /// edge is hard (and thus upstream nullability propagation should try to make
   /// the source node non-nullable, if possible).
   bool get isUpstreamTriggered;

   /// Information about the graph node that this edge "points away from".
   NullabilityNodeInfo? get sourceNode;
 }

 /// Information exposed to the migration client about the location in source
 /// code that led an edge to be introduced into the nullability graph.
 abstract class EdgeOriginInfo {
   /// If the proximate cause of the edge being introduced into the graph
   /// corresponds to the type of an element in an already migrated-library, the
   /// corresponding element; otherwise `null`.
   ///
   /// Note that either [node] or [element] will always be non-null.
   Element? get element;

   /// The kind of origin represented by this info.
   EdgeOriginKind? get kind;

   /// If the proximate cause of the edge being introduced into the graph
   /// corresponds to an AST node in a source file that is being migrated, the
   /// corresponding AST node; otherwise `null`.
   ///
   /// Note that either [node] or [element] will always be non-null.
   AstNode? get node;

   /// If [node] is non-null, the source file that it appears in.  Otherwise
   /// `null`.
   Source? get source;
 }

 /// An enumeration of the various kinds of edge origins created by the migration
 /// engine.
 enum EdgeOriginKind {
   alreadyMigratedType,
   alwaysNullableType,
   angularAnnotation,
   argumentErrorCheckNotNull,
   callTearOff,
   compoundAssignment,
   // See [DummyOrigin].
   dummy,
   dynamicAssignment,
   enumValue,
   expressionChecks,
   externalDynamic,
   fieldFormalParameter,
   fieldNotInitialized,
   forEachVariable,
   getterSetterCorrespondence,
   greatestLowerBound,
   ifNull,
   implicitMixinSuperCall,
   implicitNullInitializer,
   implicitNullReturn,
   implicitThis,
   inferredTypeParameterInstantiation,
   instanceCreation,
   instantiateToBounds,
   isCheckComponentType,
   isCheckMainType,
   iteratorMethodReturn,
   listLengthConstructor,
   literal,
   namedParameterNotSupplied,
   nonNullableBoolType,
   nonNullableObjectSuperclass,
   nonNullableUsage,
   nonNullAssertion,
   nullabilityComment,
   optionalFormalParameter,
   parameterInheritance,
   quiverCheckNotNull,
   returnTypeInheritance,
   stackTraceTypeOrigin,
   thisOrSuper,
   throw_,
   typedefReference,
   typeParameterInstantiation,
   uninitializedRead,
 }

 /// Interface used by the migration engine to expose information to its client
 /// about a reason for a modification to the source file.
 abstract class FixReasonInfo {}

 /// Abstract interface for assigning ids numbers to nodes, and performing
 /// lookups afterwards.
 abstract class NodeMapper extends NodeToIdMapper {
   /// Gets the node corresponding to the given [id].
   NullabilityNodeInfo? nodeForId(int? id);
 }

 /// Abstract interface for assigning ids numbers to nodes.
 abstract class NodeToIdMapper {
   /// Gets the id corresponding to the given [node].
   int idForNode(NullabilityNodeInfo node);
 }

 /// Interface used by the migration engine to expose information to its client
 /// about the decisions made during migration, and how those decisions relate to
 /// the input source code.
 abstract class NullabilityMigrationInstrumentation {
   /// Called whenever changes are decided upon for a given [source] file.
   ///
   /// The format of the changes is a map from source file offset to a list of
   /// changes to be applied at that offset.
   void changes(Source source, Map<int?, List<AtomicEdit>> changes);

   /// Called whenever an explicit [typeAnnotation] is found in the source code,
   /// to report the nullability [node] that was associated with this type.  If
   /// the migration engine determines that the [node] should be nullable, a `?`
   /// will be inserted after the type annotation.
   void explicitTypeNullability(
       Source? source, TypeAnnotation typeAnnotation, NullabilityNodeInfo? node);

   /// Called whenever reference is made to an [element] outside of the code
   /// being migrated, to report the nullability nodes associated with the type
   /// of the element.
   void externalDecoratedType(Element element, DecoratedTypeInfo decoratedType);

   /// Called whenever reference is made to an [typeParameter] outside of the
   /// code being migrated, to report the nullability nodes associated with the
   /// bound of the type parameter.
   void externalDecoratedTypeParameterBound(
       TypeParameterElement typeParameter, DecoratedTypeInfo decoratedType);

   /// Called when the migration process is finished.
   void finished();

   /// Called whenever the migration engine creates a graph edge between
   /// nullability nodes, to report information about the edge that was created,
   /// and why it was created.
   void graphEdge(EdgeInfo edge, EdgeOriginInfo originInfo);

   /// Called when the migration engine starts up, to report information about
   /// the immutable migration nodes [never] and [always] that are used as the
   /// starting point for nullability propagation.
   void immutableNodes(NullabilityNodeInfo never, NullabilityNodeInfo always);

   /// Called whenever the migration engine encounters an implicit return type
   /// associated with an AST node, to report the nullability nodes associated
   /// with the implicit return type of the AST node.
   ///
   /// [node] is the AST node having an implicit return type; it may be an
   /// executable declaration, function-typed formal parameter declaration,
   /// function type alias declaration, GenericFunctionType, or a function
   /// expression.
   void implicitReturnType(
       Source? source, AstNode node, DecoratedTypeInfo? decoratedReturnType);

   /// Called whenever the migration engine encounters an implicit type
   /// associated with an AST node, to report the nullability nodes associated
   /// with the implicit type of the AST node.
   ///
   /// [node] is the AST node having an implicit type; it may be a formal
   /// parameter, a declared identifier, or a variable in a variable declaration
   /// list.
   void implicitType(
       Source? source, AstNode? node, DecoratedTypeInfo decoratedType);

   /// Called whenever the migration engine encounters an AST node with implicit
   /// type arguments, to report the nullability nodes associated with the
   /// implicit type arguments of the AST node.
   ///
   /// [node] is the AST node having implicit type arguments; it may be a
   /// constructor redirection, function expression invocation, method
   /// invocation, instance creation expression, list/map/set literal, or type
   /// annotation.
   void implicitTypeArguments(
       Source? source, AstNode node, Iterable<DecoratedTypeInfo> types);

   /// Clear any data from the propagation step in preparation for that step
   /// being re-run.
   void prepareForUpdate();
 }

 /// Information exposed to the migration client about a single node in the
 /// nullability graph.
 abstract class NullabilityNodeInfo implements FixReasonInfo {
   /// List of compound nodes wrapping this node.
   final List<NullabilityNodeInfo> outerCompoundNodes = <NullabilityNodeInfo>[];

   /// Source code location corresponding to this nullability node, or `null` if
   /// not known.
   CodeReference? get codeReference;

   /// Some nodes get nullability from downstream, so the downstream edges are
   /// available to query as well.
   Iterable<EdgeInfo> get downstreamEdges;

   /// The hint actions users can perform on this node, indexed by the type of
   /// hint.
   ///
   /// Each edit is represented as a [Map<int, List<AtomicEdit>>] as is typical
   /// of [AtomicEdit]s since they do not have an offset. See extensions
   /// [AtomicEditMap] and [AtomicEditList] for usage.
   Map<HintActionKind, Map<int?, List<AtomicEdit>>> get hintActions;

   /// After migration is complete, this getter can be used to query whether
   /// the type associated with this node was determined to be "exact nullable."
   bool get isExactNullable;

   /// Indicates whether the node is immutable.  The only immutable nodes in the
   /// nullability graph are the nodes `never` and `always` that are used as the
   /// starting points for nullability propagation.
   bool get isImmutable;

   /// After migration is complete, this getter can be used to query whether
   /// the type associated with this node was determined to be nullable.
   bool get isNullable;

   /// The edges that caused this node to have the nullability that it has.
   Iterable<EdgeInfo> get upstreamEdges;

   /// If [isNullable] is false, the propagation step that caused this node to
   /// become non-nullable (if any).
   UpstreamPropagationStepInfo? get whyNotNullable;

   /// If [isNullable] is true, the propagation step that caused this node to
   /// become nullable.
   DownstreamPropagationStepInfo? get whyNullable;
 }

 abstract class PropagationStepInfo {
   CodeReference? get codeReference;

   /// The nullability edge associated with this propagation step, if any.
   /// Otherwise `null`.
   EdgeInfo? get edge;
 }

 /// Reason information for a simple fix that isn't associated with any edges or
 /// nodes.
 abstract class SimpleFixReasonInfo implements FixReasonInfo {
   /// Code location of the fix.
   CodeReference get codeReference;

   /// Description of the fix.
   String get description;
 }

 /// A simple implementation of [NodeMapper] that assigns ids to nodes as they
 /// are requested, backed by a map.
 ///
 /// Be careful not to leak references to nodes by holding on to this beyond the
 /// lifetime of the nodes it maps.
 class SimpleNodeMapper extends NodeMapper {
   final _nodeToId = <NullabilityNodeInfo, int>{};
   final _idToNode = <int, NullabilityNodeInfo>{};

   @override
   int idForNode(NullabilityNodeInfo node) {
     final id = _nodeToId.putIfAbsent(node, () => _nodeToId.length);
     _idToNode.putIfAbsent(id, () => node);
     return id;
   }

   @override
   NullabilityNodeInfo? nodeForId(int? id) => _idToNode[id!];
 }

 /// Information exposed to the migration client about a node in the nullability
 /// graph resulting from a type substitution.
 abstract class SubstitutionNodeInfo extends NullabilityNodeInfo {
   /// Nullability node representing the inner type of the substitution.
   ///
   /// For example, if this NullabilityNode arose from substituting `int*` for
   /// `T` in the type `T*`, [innerNode] is the nullability corresponding to the
   /// `*` in `int*`.
   NullabilityNodeInfo get innerNode;

   /// Nullability node representing the outer type of the substitution.
   ///
   /// For example, if this NullabilityNode arose from substituting `int*` for
   /// `T` in the type `T*`, [innerNode] is the nullability corresponding to the
   /// `*` in `T*`.
   NullabilityNodeInfo get outerNode;
 }

 /// Information about a propagation step that occurred during upstream
 /// propagation.
 abstract class UpstreamPropagationStepInfo implements PropagationStepInfo {
   bool get isStartingPoint;

   /// The node whose nullability was changed.
   ///
   /// Any propagation step that took effect should have a non-null value here.
   /// Propagation steps that are pending but have not taken effect yet, or that
   /// never had an effect (e.g. because an edge was not triggered) will have a
   /// `null` value for this field.
   NullabilityNodeInfo get node;

   UpstreamPropagationStepInfo? get principalCause;
 }
	// Copyright (c) 2019, 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.

	import 'package:analyzer/dart/ast/ast.dart';
	import 'package:analyzer/dart/element/element.dart';
	import 'package:analyzer/dart/element/type.dart';
	import 'package:analyzer/src/generated/source.dart';
	import 'package:nnbd_migration/src/edit_plan.dart';
	import 'package:nnbd_migration/src/hint_action.dart';

	/// Data structure used by the nullability migration engine to refer to a
	/// specific location in source code.
	class CodeReference {
	final String path;

	final int line;

	final int column;

	final int offset;

	/// Name of the enclosing function, or `null` if not known.
	String? function;

	CodeReference(this.path, this.offset, this.line, this.column, this.function);

	/// Creates a [CodeReference] pointing to the given [node].
	factory CodeReference.fromAstNode(AstNode node) {
	var compilationUnit = node.thisOrAncestorOfType<CompilationUnit>()!;
	var source = compilationUnit.declaredElement!.source;
	var location = compilationUnit.lineInfo!.getLocation(node.offset);
	return CodeReference(source.fullName, node.offset, location.lineNumber,
	location.columnNumber, _computeEnclosingName(node));
	}

	factory CodeReference.fromElement(
	Element element, LineInfo Function(String) getLineInfo) {
	var path = element.source!.fullName;
	var offset = element.nameOffset;
	var location = getLineInfo(path).getLocation(offset);
	return CodeReference(path, offset, location.lineNumber,
	location.columnNumber, _computeElementFullName(element));
	}

	/// Gets a short description of this code reference (using the last component
	/// of the path rather than the full path)
	String get shortName => '$shortPath:$line:$column';

	/// Gets the last component of the path part of this code reference.
	String get shortPath {
	var pathAsUri = Uri.file(path);
	return pathAsUri.pathSegments.last;
	}

	@override
	String toString() {
	var pathAsUri = Uri.file(path);
	return '${function ?? 'unknown'} ($pathAsUri:$line:$column)';
	}

	static String? _computeElementFullName(Element? element) {
	List<String> parts = [];
	while (element != null) {
	var elementName = _computeElementName(element);
	if (elementName != null) {
	parts.add(elementName);
	}
	element = element.enclosingElement;
	}
	if (parts.isEmpty) return null;
	return parts.reversed.join('.');
	}

	static String? _computeElementName(Element element) {
	if (element is CompilationUnitElement \|\| element is LibraryElement) {
	return null;
	}
	return element.name;
	}

	static String? _computeEnclosingName(AstNode? node) {
	List<String?> parts = [];
	while (node != null) {
	var nodeName = _computeNodeDeclarationName(node);
	if (nodeName != null) {
	parts.add(nodeName);
	} else if (parts.isEmpty && node is VariableDeclarationList) {
	parts.add(node.variables.first.declaredElement!.name);
	}
	node = node.parent;
	}
	if (parts.isEmpty) return null;
	return parts.reversed.join('.');
	}

	static String? _computeNodeDeclarationName(AstNode node) {
	if (node is ExtensionDeclaration) {
	return node.declaredElement?.name ?? '<unnamed extension>';
	} else if (node is Declaration) {
	var name = node.declaredElement?.name;
	return name == '' ? '<unnamed>' : name;
	} else {
	return null;
	}
	}
	}

	/// Information exposed to the migration client about the set of nullability
	/// nodes decorating a type in the program being migrated.
	abstract class DecoratedTypeInfo {
	/// Information about the graph node associated with the decision of whether
	/// or not to make this type into a nullable type.
	NullabilityNodeInfo? get node;

	/// If [type] is a function type, information about the set of nullability
	/// nodes decorating the type's return type.
	DecoratedTypeInfo? get returnType;

	/// The original (pre-migration) type that is being migrated.
	DartType? get type;

	/// If [type] is a function type, looks up information about the set of
	/// nullability nodes decorating one of the type's named parameter types.
	DecoratedTypeInfo? namedParameter(String name);

	/// If [type] is a function type, looks up information about the set of
	/// nullability nodes decorating one of the type's positional parameter types.
	/// (This could be an optional or a required positional parameter).
	DecoratedTypeInfo? positionalParameter(int i);

	/// If [type] is an interface type, looks up information about the set of
	/// nullability nodes decorating one of the type's type arguments.
	DecoratedTypeInfo? typeArgument(int i);
	}

	/// Information about a propagation step that occurred during downstream
	/// propagation.
	abstract class DownstreamPropagationStepInfo implements PropagationStepInfo {
	DownstreamPropagationStepInfo? get principalCause;

	/// The node whose nullability was changed.
	///
	/// Any propagation step that took effect should have a non-null value here.
	/// Propagation steps that are pending but have not taken effect yet, or that
	/// never had an effect (e.g. because an edge was not triggered) will have a
	/// `null` value for this field.
	NullabilityNodeInfo? get targetNode;
	}

	/// Information exposed to the migration client about an edge in the nullability
	/// graph.
	///
	/// A graph edge represents a dependency relationship between two types being
	/// migrated, suggesting that if one type (the source) is made nullable, it may
	/// be desirable to make the other type (the destination) nullable as well.
	abstract class EdgeInfo implements FixReasonInfo {
	/// User-friendly description of the edge, or `null` if not known.
	String get description;

	/// Information about the graph node that this edge "points to".
	NullabilityNodeInfo get destinationNode;

	/// The set of "guard nodes" for this edge. Guard nodes are graph nodes whose
	/// nullability determines whether it is important to satisfy a graph edge.
	/// If at least one of an edge's guards is non-nullable, then it is not
	/// important to satisfy the graph edge. (Typically this is because the code
	/// that led to the graph edge being created is only reachable if the guards
	/// are all nullable).
	Iterable<NullabilityNodeInfo?> get guards;

	/// A boolean indicating whether the graph edge is a "hard" edge. Hard edges
	/// are associated with unconditional control flow, and thus allow information
	/// about non-nullability to be propagated "upstream" through the nullability
	/// graph.
	bool get isHard;

	/// A boolean indicating whether the graph edge is "satisfied". At its heart,
	/// the nullability propagation algorithm is an effort to satisfy graph edges
	/// in a way that corresponds to the user's intent. A graph edge is
	/// considered satisfied if any of the following is true:
	/// - Its [sourceNode] is non-nullable.
	/// - One of its [guards] is non-nullable.
	/// - Its [destinationNode] is nullable.
	bool get isSatisfied;

	/// Indicates whether all the upstream nodes of this edge are nullable (and
	/// thus downstream nullability propagation should try to make the destination
	/// node nullable, if possible).
	bool get isTriggered;

	/// A boolean indicating whether the graph edge is a "union" edge. Union
	/// edges are edges for which the nullability propagation algorithm tries to
	/// ensure that both the [sourceNode] and the [destinationNode] have the
	/// same nullability. Typically these are associated with situations where
	/// Dart language semantics require two types to be the same type (e.g. a type
	/// formal bound on a generic function type in a base class, and the
	/// corresponding type formal bound on a generic function type in an
	/// overriding class).
	///
	/// The [isHard] property is always true for union edges.
	bool get isUnion;

	/// Indicates whether the downstream node of this edge is non-nullable and the
	/// edge is hard (and thus upstream nullability propagation should try to make
	/// the source node non-nullable, if possible).
	bool get isUpstreamTriggered;

	/// Information about the graph node that this edge "points away from".
	NullabilityNodeInfo? get sourceNode;
	}

	/// Information exposed to the migration client about the location in source
	/// code that led an edge to be introduced into the nullability graph.
	abstract class EdgeOriginInfo {
	/// If the proximate cause of the edge being introduced into the graph
	/// corresponds to the type of an element in an already migrated-library, the
	/// corresponding element; otherwise `null`.
	///
	/// Note that either [node] or [element] will always be non-null.
	Element? get element;

	/// The kind of origin represented by this info.
	EdgeOriginKind? get kind;

	/// If the proximate cause of the edge being introduced into the graph
	/// corresponds to an AST node in a source file that is being migrated, the
	/// corresponding AST node; otherwise `null`.
	///
	/// Note that either [node] or [element] will always be non-null.
	AstNode? get node;

	/// If [node] is non-null, the source file that it appears in. Otherwise
	/// `null`.
	Source? get source;
	}

	/// An enumeration of the various kinds of edge origins created by the migration
	/// engine.
	enum EdgeOriginKind {
	alreadyMigratedType,
	alwaysNullableType,
	angularAnnotation,
	argumentErrorCheckNotNull,
	callTearOff,
	compoundAssignment,
	// See [DummyOrigin].
	dummy,
	dynamicAssignment,
	enumValue,
	expressionChecks,
	externalDynamic,
	fieldFormalParameter,
	fieldNotInitialized,
	forEachVariable,
	getterSetterCorrespondence,
	greatestLowerBound,
	ifNull,
	implicitMixinSuperCall,
	implicitNullInitializer,
	implicitNullReturn,
	implicitThis,
	inferredTypeParameterInstantiation,
	instanceCreation,
	instantiateToBounds,
	isCheckComponentType,
	isCheckMainType,
	iteratorMethodReturn,
	listLengthConstructor,
	literal,
	namedParameterNotSupplied,
	nonNullableBoolType,
	nonNullableObjectSuperclass,
	nonNullableUsage,
	nonNullAssertion,
	nullabilityComment,
	optionalFormalParameter,
	parameterInheritance,
	quiverCheckNotNull,
	returnTypeInheritance,
	stackTraceTypeOrigin,
	thisOrSuper,
	throw_,
	typedefReference,
	typeParameterInstantiation,
	uninitializedRead,
	}

	/// Interface used by the migration engine to expose information to its client
	/// about a reason for a modification to the source file.
	abstract class FixReasonInfo {}

	/// Abstract interface for assigning ids numbers to nodes, and performing
	/// lookups afterwards.
	abstract class NodeMapper extends NodeToIdMapper {
	/// Gets the node corresponding to the given [id].
	NullabilityNodeInfo? nodeForId(int? id);
	}

	/// Abstract interface for assigning ids numbers to nodes.
	abstract class NodeToIdMapper {
	/// Gets the id corresponding to the given [node].
	int idForNode(NullabilityNodeInfo node);
	}

	/// Interface used by the migration engine to expose information to its client
	/// about the decisions made during migration, and how those decisions relate to
	/// the input source code.
	abstract class NullabilityMigrationInstrumentation {
	/// Called whenever changes are decided upon for a given [source] file.
	///
	/// The format of the changes is a map from source file offset to a list of
	/// changes to be applied at that offset.
	void changes(Source source, Map<int?, List<AtomicEdit>> changes);

	/// Called whenever an explicit [typeAnnotation] is found in the source code,
	/// to report the nullability [node] that was associated with this type. If
	/// the migration engine determines that the [node] should be nullable, a `?`
	/// will be inserted after the type annotation.
	void explicitTypeNullability(
	Source? source, TypeAnnotation typeAnnotation, NullabilityNodeInfo? node);

	/// Called whenever reference is made to an [element] outside of the code
	/// being migrated, to report the nullability nodes associated with the type
	/// of the element.
	void externalDecoratedType(Element element, DecoratedTypeInfo decoratedType);

	/// Called whenever reference is made to an [typeParameter] outside of the
	/// code being migrated, to report the nullability nodes associated with the
	/// bound of the type parameter.
	void externalDecoratedTypeParameterBound(
	TypeParameterElement typeParameter, DecoratedTypeInfo decoratedType);

	/// Called when the migration process is finished.
	void finished();

	/// Called whenever the migration engine creates a graph edge between
	/// nullability nodes, to report information about the edge that was created,
	/// and why it was created.
	void graphEdge(EdgeInfo edge, EdgeOriginInfo originInfo);

	/// Called when the migration engine starts up, to report information about
	/// the immutable migration nodes [never] and [always] that are used as the
	/// starting point for nullability propagation.
	void immutableNodes(NullabilityNodeInfo never, NullabilityNodeInfo always);

	/// Called whenever the migration engine encounters an implicit return type
	/// associated with an AST node, to report the nullability nodes associated
	/// with the implicit return type of the AST node.
	///
	/// [node] is the AST node having an implicit return type; it may be an
	/// executable declaration, function-typed formal parameter declaration,
	/// function type alias declaration, GenericFunctionType, or a function
	/// expression.
	void implicitReturnType(
	Source? source, AstNode node, DecoratedTypeInfo? decoratedReturnType);

	/// Called whenever the migration engine encounters an implicit type
	/// associated with an AST node, to report the nullability nodes associated
	/// with the implicit type of the AST node.
	///
	/// [node] is the AST node having an implicit type; it may be a formal
	/// parameter, a declared identifier, or a variable in a variable declaration
	/// list.
	void implicitType(
	Source? source, AstNode? node, DecoratedTypeInfo decoratedType);

	/// Called whenever the migration engine encounters an AST node with implicit
	/// type arguments, to report the nullability nodes associated with the
	/// implicit type arguments of the AST node.
	///
	/// [node] is the AST node having implicit type arguments; it may be a
	/// constructor redirection, function expression invocation, method
	/// invocation, instance creation expression, list/map/set literal, or type
	/// annotation.
	void implicitTypeArguments(
	Source? source, AstNode node, Iterable<DecoratedTypeInfo> types);

	/// Clear any data from the propagation step in preparation for that step
	/// being re-run.
	void prepareForUpdate();
	}

	/// Information exposed to the migration client about a single node in the
	/// nullability graph.
	abstract class NullabilityNodeInfo implements FixReasonInfo {
	/// List of compound nodes wrapping this node.
	final List<NullabilityNodeInfo> outerCompoundNodes = <NullabilityNodeInfo>[];

	/// Source code location corresponding to this nullability node, or `null` if
	/// not known.
	CodeReference? get codeReference;

	/// Some nodes get nullability from downstream, so the downstream edges are
	/// available to query as well.
	Iterable<EdgeInfo> get downstreamEdges;

	/// The hint actions users can perform on this node, indexed by the type of
	/// hint.
	///
	/// Each edit is represented as a [Map<int, List<AtomicEdit>>] as is typical
	/// of [AtomicEdit]s since they do not have an offset. See extensions
	/// [AtomicEditMap] and [AtomicEditList] for usage.
	Map<HintActionKind, Map<int?, List<AtomicEdit>>> get hintActions;

	/// After migration is complete, this getter can be used to query whether
	/// the type associated with this node was determined to be "exact nullable."
	bool get isExactNullable;

	/// Indicates whether the node is immutable. The only immutable nodes in the
	/// nullability graph are the nodes `never` and `always` that are used as the
	/// starting points for nullability propagation.
	bool get isImmutable;

	/// After migration is complete, this getter can be used to query whether
	/// the type associated with this node was determined to be nullable.
	bool get isNullable;

	/// The edges that caused this node to have the nullability that it has.
	Iterable<EdgeInfo> get upstreamEdges;

	/// If [isNullable] is false, the propagation step that caused this node to
	/// become non-nullable (if any).
	UpstreamPropagationStepInfo? get whyNotNullable;

	/// If [isNullable] is true, the propagation step that caused this node to
	/// become nullable.
	DownstreamPropagationStepInfo? get whyNullable;
	}

	abstract class PropagationStepInfo {
	CodeReference? get codeReference;

	/// The nullability edge associated with this propagation step, if any.
	/// Otherwise `null`.
	EdgeInfo? get edge;
	}

	/// Reason information for a simple fix that isn't associated with any edges or
	/// nodes.
	abstract class SimpleFixReasonInfo implements FixReasonInfo {
	/// Code location of the fix.
	CodeReference get codeReference;

	/// Description of the fix.
	String get description;
	}

	/// A simple implementation of [NodeMapper] that assigns ids to nodes as they
	/// are requested, backed by a map.
	///
	/// Be careful not to leak references to nodes by holding on to this beyond the
	/// lifetime of the nodes it maps.
	class SimpleNodeMapper extends NodeMapper {
	final _nodeToId = <NullabilityNodeInfo, int>{};
	final _idToNode = <int, NullabilityNodeInfo>{};

	@override
	int idForNode(NullabilityNodeInfo node) {
	final id = _nodeToId.putIfAbsent(node, () => _nodeToId.length);
	_idToNode.putIfAbsent(id, () => node);
	return id;
	}

	@override
	NullabilityNodeInfo? nodeForId(int? id) => _idToNode[id!];
	}

	/// Information exposed to the migration client about a node in the nullability
	/// graph resulting from a type substitution.
	abstract class SubstitutionNodeInfo extends NullabilityNodeInfo {
	/// Nullability node representing the inner type of the substitution.
	///
	/// For example, if this NullabilityNode arose from substituting `int*` for
	/// `T` in the type `T*`, [innerNode] is the nullability corresponding to the
	/// `` in `int`.
	NullabilityNodeInfo get innerNode;

	/// Nullability node representing the outer type of the substitution.
	///
	/// For example, if this NullabilityNode arose from substituting `int*` for
	/// `T` in the type `T*`, [innerNode] is the nullability corresponding to the
	/// `` in `T`.
	NullabilityNodeInfo get outerNode;
	}

	/// Information about a propagation step that occurred during upstream
	/// propagation.
	abstract class UpstreamPropagationStepInfo implements PropagationStepInfo {
	bool get isStartingPoint;

	/// The node whose nullability was changed.
	///
	/// Any propagation step that took effect should have a non-null value here.
	/// Propagation steps that are pending but have not taken effect yet, or that
	/// never had an effect (e.g. because an edge was not triggered) will have a
	/// `null` value for this field.
	NullabilityNodeInfo get node;

	UpstreamPropagationStepInfo? get principalCause;
	}