pkg/analyzer/lib/src/dart/resolver/function_expression_resolver.dart - sdk.git - Git at Google

 // Copyright (c) 2020, 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/dart/ast/ast.dart';
 import 'package:analyzer/src/dart/element/element.dart';
 import 'package:analyzer/src/dart/element/type.dart';
 import 'package:analyzer/src/dart/element/type_system.dart';
 import 'package:analyzer/src/dart/resolver/invocation_inference_helper.dart';
 import 'package:analyzer/src/generated/migration.dart';
 import 'package:analyzer/src/generated/resolver.dart';
 import 'package:collection/collection.dart';

 class FunctionExpressionResolver {
   final ResolverVisitor _resolver;
   final MigrationResolutionHooks? _migrationResolutionHooks;
   final InvocationInferenceHelper _inferenceHelper;

   FunctionExpressionResolver({
     required ResolverVisitor resolver,
     required MigrationResolutionHooks? migrationResolutionHooks,
   })  : _resolver = resolver,
         _migrationResolutionHooks = migrationResolutionHooks,
         _inferenceHelper = resolver.inferenceHelper;

   bool get _isNonNullableByDefault => _typeSystem.isNonNullableByDefault;

   TypeSystemImpl get _typeSystem => _resolver.typeSystem;

   void resolve(FunctionExpressionImpl node, {required DartType? contextType}) {
     var parent = node.parent;
     // Note: `isFunctionDeclaration` must have an explicit type to work around
     // https://github.com/dart-lang/language/issues/1785.
     bool isFunctionDeclaration = parent is FunctionDeclaration;
     var body = node.body;

     if (_resolver.flowAnalysis.flow != null && !isFunctionDeclaration) {
       _resolver.flowAnalysis
           .executableDeclaration_enter(node, node.parameters, isClosure: true);
     }

     bool wasFunctionTypeSupplied = contextType is FunctionType;
     node.wasFunctionTypeSupplied = wasFunctionTypeSupplied;
     DartType? imposedType;
     if (wasFunctionTypeSupplied) {
       var instantiatedType = _matchTypeParameters(
         node.typeParameters,
         contextType,
       );
       if (instantiatedType is FunctionType) {
         _inferFormalParameters(node.parameters, instantiatedType);
         var returnType = instantiatedType.returnType;
         if (!returnType.isDynamic) {
           imposedType = returnType;
         }
       }
     }

     node.typeParameters?.accept(_resolver);
     node.parameters?.accept(_resolver);
     imposedType = node.body.resolve(_resolver, imposedType);
     if (isFunctionDeclaration) {
       // A side effect of visiting the children is that the parameters are now
       // in scope, so we can visit the documentation comment now.
       parent.documentationComment?.accept(_resolver);
     }
     _resolve2(node, imposedType, contextType: contextType);

     if (_resolver.flowAnalysis.flow != null && !isFunctionDeclaration) {
       _resolver.checkForBodyMayCompleteNormally(
         body: body,
         errorNode: body,
       );
       _resolver.flowAnalysis.flow?.functionExpression_end();
       _resolver.nullSafetyDeadCodeVerifier.flowEnd(node);
     }
   }

   /// Infer types of implicitly typed formal parameters.
   void _inferFormalParameters(
     FormalParameterList? node,
     FunctionType contextType,
   ) {
     if (node == null) {
       return;
     }

     void inferType(ParameterElementImpl p, DartType inferredType) {
       // Check that there is no declared type, and that we have not already
       // inferred a type in some fashion.
       if (p.hasImplicitType && p.type.isDynamic) {
         // If no type is declared for a parameter and there is a
         // corresponding parameter in the context type schema with type
         // schema `K`, the parameter is given an inferred type `T` where `T`
         // is derived from `K` as follows.
         inferredType = _typeSystem.greatestClosureOfSchema(inferredType);

         // If the greatest closure of `K` is `S` and `S` is a subtype of
         // `Null`, then `T` is `Object?`. Otherwise, `T` is `S`.
         if (_typeSystem.isSubtypeOf(inferredType, _typeSystem.nullNone)) {
           inferredType = _isNonNullableByDefault
               ? _typeSystem.objectQuestion
               : _typeSystem.objectStar;
         }
         if (_migrationResolutionHooks != null) {
           inferredType = _migrationResolutionHooks!
               .modifyInferredParameterType(p, inferredType);
         } else {
           inferredType = _typeSystem.nonNullifyLegacy(inferredType);
         }
         if (!inferredType.isDynamic) {
           p.type = inferredType;
         }
       }
     }

     var parameters = node.parameterElements.whereNotNull();
     {
       Iterator<ParameterElement> positional =
           parameters.where((p) => p.isPositional).iterator;
       Iterator<ParameterElement> fnPositional =
           contextType.parameters.where((p) => p.isPositional).iterator;
       while (positional.moveNext() && fnPositional.moveNext()) {
         inferType(positional.current as ParameterElementImpl,
             fnPositional.current.type);
       }
     }

     {
       Map<String, DartType> namedParameterTypes =
           contextType.namedParameterTypes;
       Iterable<ParameterElement> named = parameters.where((p) => p.isNamed);
       for (var p in named) {
         if (!namedParameterTypes.containsKey(p.name)) {
           continue;
         }
         inferType(p as ParameterElementImpl, namedParameterTypes[p.name]!);
       }
     }
   }

   /// Given the downward inference [type], return the function type expressed
   /// in terms of the type parameters from [typeParameterList].
   ///
   /// Return `null` is the number of element in [typeParameterList] is not
   /// the same as the number of type parameters in the [type].
   FunctionType? _matchTypeParameters(
       TypeParameterList? typeParameterList, FunctionType type) {
     if (typeParameterList == null) {
       if (type.typeFormals.isEmpty) {
         return type;
       }
       return null;
     }

     var typeParameters = typeParameterList.typeParameters;
     if (typeParameters.length != type.typeFormals.length) {
       return null;
     }

     return type.instantiate(typeParameters.map((typeParameter) {
       return typeParameter.declaredElement!.instantiate(
         nullabilitySuffix: _resolver.noneOrStarSuffix,
       );
     }).toList());
   }

   void _resolve2(FunctionExpressionImpl node, DartType? imposedType,
       {required DartType? contextType}) {
     var functionElement = node.declaredElement as ExecutableElementImpl;

     if (_shouldUpdateReturnType(node)) {
       functionElement.returnType = imposedType ?? DynamicTypeImpl.instance;
     }

     _inferenceHelper.recordStaticType(node, functionElement.type,
         contextType: contextType);
   }

   static bool _shouldUpdateReturnType(FunctionExpression node) {
     var parent = node.parent;
     if (parent is FunctionDeclaration) {
       // Local function without declared return type.
       return parent.parent is FunctionDeclarationStatement &&
           parent.returnType == null;
     } else {
       // Pure function expression.
       return true;
     }
   }
 }
	// Copyright (c) 2020, 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/dart/ast/ast.dart';
	import 'package:analyzer/src/dart/element/element.dart';
	import 'package:analyzer/src/dart/element/type.dart';
	import 'package:analyzer/src/dart/element/type_system.dart';
	import 'package:analyzer/src/dart/resolver/invocation_inference_helper.dart';
	import 'package:analyzer/src/generated/migration.dart';
	import 'package:analyzer/src/generated/resolver.dart';
	import 'package:collection/collection.dart';

	class FunctionExpressionResolver {
	final ResolverVisitor _resolver;
	final MigrationResolutionHooks? _migrationResolutionHooks;
	final InvocationInferenceHelper _inferenceHelper;

	FunctionExpressionResolver({
	required ResolverVisitor resolver,
	required MigrationResolutionHooks? migrationResolutionHooks,
	}) : _resolver = resolver,
	_migrationResolutionHooks = migrationResolutionHooks,
	_inferenceHelper = resolver.inferenceHelper;

	bool get _isNonNullableByDefault => _typeSystem.isNonNullableByDefault;

	TypeSystemImpl get _typeSystem => _resolver.typeSystem;

	void resolve(FunctionExpressionImpl node, {required DartType? contextType}) {
	var parent = node.parent;
	// Note: `isFunctionDeclaration` must have an explicit type to work around
	// https://github.com/dart-lang/language/issues/1785.
	bool isFunctionDeclaration = parent is FunctionDeclaration;
	var body = node.body;

	if (_resolver.flowAnalysis.flow != null && !isFunctionDeclaration) {
	_resolver.flowAnalysis
	.executableDeclaration_enter(node, node.parameters, isClosure: true);
	}

	bool wasFunctionTypeSupplied = contextType is FunctionType;
	node.wasFunctionTypeSupplied = wasFunctionTypeSupplied;
	DartType? imposedType;
	if (wasFunctionTypeSupplied) {
	var instantiatedType = _matchTypeParameters(
	node.typeParameters,
	contextType,
	);
	if (instantiatedType is FunctionType) {
	_inferFormalParameters(node.parameters, instantiatedType);
	var returnType = instantiatedType.returnType;
	if (!returnType.isDynamic) {
	imposedType = returnType;
	}
	}
	}

	node.typeParameters?.accept(_resolver);
	node.parameters?.accept(_resolver);
	imposedType = node.body.resolve(_resolver, imposedType);
	if (isFunctionDeclaration) {
	// A side effect of visiting the children is that the parameters are now
	// in scope, so we can visit the documentation comment now.
	parent.documentationComment?.accept(_resolver);
	}
	_resolve2(node, imposedType, contextType: contextType);

	if (_resolver.flowAnalysis.flow != null && !isFunctionDeclaration) {
	_resolver.checkForBodyMayCompleteNormally(
	body: body,
	errorNode: body,
	);
	_resolver.flowAnalysis.flow?.functionExpression_end();
	_resolver.nullSafetyDeadCodeVerifier.flowEnd(node);
	}
	}

	/// Infer types of implicitly typed formal parameters.
	void _inferFormalParameters(
	FormalParameterList? node,
	FunctionType contextType,
	) {
	if (node == null) {
	return;
	}

	void inferType(ParameterElementImpl p, DartType inferredType) {
	// Check that there is no declared type, and that we have not already
	// inferred a type in some fashion.
	if (p.hasImplicitType && p.type.isDynamic) {
	// If no type is declared for a parameter and there is a
	// corresponding parameter in the context type schema with type
	// schema `K`, the parameter is given an inferred type `T` where `T`
	// is derived from `K` as follows.
	inferredType = _typeSystem.greatestClosureOfSchema(inferredType);

	// If the greatest closure of `K` is `S` and `S` is a subtype of
	// `Null`, then `T` is `Object?`. Otherwise, `T` is `S`.
	if (_typeSystem.isSubtypeOf(inferredType, _typeSystem.nullNone)) {
	inferredType = _isNonNullableByDefault
	? _typeSystem.objectQuestion
	: _typeSystem.objectStar;
	}
	if (_migrationResolutionHooks != null) {
	inferredType = _migrationResolutionHooks!
	.modifyInferredParameterType(p, inferredType);
	} else {
	inferredType = _typeSystem.nonNullifyLegacy(inferredType);
	}
	if (!inferredType.isDynamic) {
	p.type = inferredType;
	}
	}
	}

	var parameters = node.parameterElements.whereNotNull();
	{
	Iterator<ParameterElement> positional =
	parameters.where((p) => p.isPositional).iterator;
	Iterator<ParameterElement> fnPositional =
	contextType.parameters.where((p) => p.isPositional).iterator;
	while (positional.moveNext() && fnPositional.moveNext()) {
	inferType(positional.current as ParameterElementImpl,
	fnPositional.current.type);
	}
	}

	{
	Map<String, DartType> namedParameterTypes =
	contextType.namedParameterTypes;
	Iterable<ParameterElement> named = parameters.where((p) => p.isNamed);
	for (var p in named) {
	if (!namedParameterTypes.containsKey(p.name)) {
	continue;
	}
	inferType(p as ParameterElementImpl, namedParameterTypes[p.name]!);
	}
	}
	}

	/// Given the downward inference [type], return the function type expressed
	/// in terms of the type parameters from [typeParameterList].
	///
	/// Return `null` is the number of element in [typeParameterList] is not
	/// the same as the number of type parameters in the [type].
	FunctionType? _matchTypeParameters(
	TypeParameterList? typeParameterList, FunctionType type) {
	if (typeParameterList == null) {
	if (type.typeFormals.isEmpty) {
	return type;
	}
	return null;
	}

	var typeParameters = typeParameterList.typeParameters;
	if (typeParameters.length != type.typeFormals.length) {
	return null;
	}

	return type.instantiate(typeParameters.map((typeParameter) {
	return typeParameter.declaredElement!.instantiate(
	nullabilitySuffix: _resolver.noneOrStarSuffix,
	);
	}).toList());
	}

	void _resolve2(FunctionExpressionImpl node, DartType? imposedType,
	{required DartType? contextType}) {
	var functionElement = node.declaredElement as ExecutableElementImpl;

	if (_shouldUpdateReturnType(node)) {
	functionElement.returnType = imposedType ?? DynamicTypeImpl.instance;
	}

	_inferenceHelper.recordStaticType(node, functionElement.type,
	contextType: contextType);
	}

	static bool _shouldUpdateReturnType(FunctionExpression node) {
	var parent = node.parent;
	if (parent is FunctionDeclaration) {
	// Local function without declared return type.
	return parent.parent is FunctionDeclarationStatement &&
	parent.returnType == null;
	} else {
	// Pure function expression.
	return true;
	}
	}
	}