pkg/analyzer/lib/src/error/return_type_verifier.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/nullability_suffix.dart';
 import 'package:analyzer/dart/element/type.dart';
 import 'package:analyzer/error/listener.dart';
 import 'package:analyzer/src/dart/ast/extensions.dart';
 import 'package:analyzer/src/dart/element/type.dart';
 import 'package:analyzer/src/dart/element/type_provider.dart';
 import 'package:analyzer/src/dart/element/type_system.dart';
 import 'package:analyzer/src/error/analyzer_error_code.dart';
 import 'package:analyzer/src/error/codes.dart';
 import 'package:analyzer/src/generated/error_verifier.dart';

 class ReturnTypeVerifier {
   final TypeProviderImpl _typeProvider;
   final TypeSystemImpl _typeSystem;
   final ErrorReporter _errorReporter;

   late EnclosingExecutableContext enclosingExecutable;

   ReturnTypeVerifier({
     required TypeProviderImpl typeProvider,
     required TypeSystemImpl typeSystem,
     required ErrorReporter errorReporter,
   })  : _typeProvider = typeProvider,
         _typeSystem = typeSystem,
         _errorReporter = errorReporter;

   DartType get _flattenedReturnType {
     var returnType = enclosingExecutable.returnType;
     if (enclosingExecutable.isSynchronous) {
       return returnType;
     } else {
       return _typeSystem.flatten(returnType);
     }
   }

   void verifyExpressionFunctionBody(ExpressionFunctionBody node) {
     // This enables concise declarations of void functions.
     if (_flattenedReturnType.isVoid) {
       return;
     }

     return _checkReturnExpression(node.expression);
   }

   void verifyReturnStatement(ReturnStatement statement) {
     var expression = statement.expression;

     if (enclosingExecutable.isGenerativeConstructor) {
       if (expression != null) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_IN_GENERATIVE_CONSTRUCTOR,
           expression,
         );
       }
       return;
     }

     if (enclosingExecutable.isGenerator) {
       return;
     }

     if (expression == null) {
       _checkReturnWithoutValue(statement);
       return;
     }

     _checkReturnExpression(expression);
   }

   void verifyReturnType(TypeAnnotation? returnType) {
     // If no declared type, then the type is `dynamic`, which is valid.
     if (returnType == null) {
       return;
     }

     void checkElement(
       ClassElement expectedElement,
       AnalyzerErrorCode errorCode,
     ) {
       void reportError() {
         enclosingExecutable.hasLegalReturnType = false;
         _errorReporter.reportErrorForNode(errorCode, returnType);
       }

       // It is a compile-time error if the declared return type of
       // a function marked `sync*` or `async*` is `void`.
       if (enclosingExecutable.isGenerator) {
         if (enclosingExecutable.returnType.isVoid) {
           return reportError();
         }
       }

       // It is a compile-time error if the declared return type of
       // a function marked `...` is not a supertype of `...`.
       if (!_isLegalReturnType(expectedElement)) {
         return reportError();
       }
     }

     if (enclosingExecutable.isAsynchronous) {
       if (enclosingExecutable.isGenerator) {
         checkElement(
           _typeProvider.streamElement,
           CompileTimeErrorCode.ILLEGAL_ASYNC_GENERATOR_RETURN_TYPE,
         );
       } else {
         checkElement(
           _typeProvider.futureElement,
           CompileTimeErrorCode.ILLEGAL_ASYNC_RETURN_TYPE,
         );
       }
     } else if (enclosingExecutable.isGenerator) {
       checkElement(
         _typeProvider.iterableElement,
         CompileTimeErrorCode.ILLEGAL_SYNC_GENERATOR_RETURN_TYPE,
       );
     }
   }

   /// Check that a type mismatch between the type of the [expression] and
   /// the expected return type of the enclosing executable.
   void _checkReturnExpression(Expression expression) {
     if (!enclosingExecutable.hasLegalReturnType) {
       // ILLEGAL_ASYNC_RETURN_TYPE has already been reported, meaning the
       // _declared_ return type is illegal; don't confuse by also reporting
       // that the type being returned here does not match that illegal return
       // type.
       return;
     }

     if (_typeSystem.isNonNullableByDefault) {
       _checkReturnExpression_nullSafety(expression);
     } else {
       _checkReturnExpression_legacy(expression);
     }
   }

   void _checkReturnExpression_legacy(Expression expression) {
     // `T` is the declared return type.
     // `S` is the static type of the expression.
     var T = enclosingExecutable.returnType;
     var S = expression.typeOrThrow;

     void reportTypeError() {
       if (enclosingExecutable.catchErrorOnErrorReturnType != null) {
         _errorReporter.reportErrorForNode(
           HintCode.RETURN_OF_INVALID_TYPE_FROM_CATCH_ERROR,
           expression,
           [S, T],
         );
       } else if (enclosingExecutable.isClosure) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CLOSURE,
           expression,
           [S, T],
         );
       } else if (enclosingExecutable.isConstructor) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       } else if (enclosingExecutable.isFunction) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_FUNCTION,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       } else if (enclosingExecutable.isMethod) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_METHOD,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       }
     }

     if (enclosingExecutable.isSynchronous) {
       // It is a compile-time error if `T` is `void`,
       // and `S` is neither `void`, `dynamic`, nor `Null`.
       if (T.isVoid) {
         if (!_isVoidDynamicOrNull(S)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `S` is `void`,
       // and `T` is neither `void`, `dynamic`, nor `Null`.
       if (S.isVoid) {
         if (!_isVoidDynamicOrNull(T)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `S` is not `void`,
       // and `S` is not assignable to `T`.
       if (!S.isVoid) {
         if (!_typeSystem.isAssignableTo(S, T)) {
           reportTypeError();
           return;
         }
       }
       // OK
       return;
     }

     if (enclosingExecutable.isAsynchronous) {
       var flatten_T = _typeSystem.flatten(T);
       var flatten_S = _typeSystem.flatten(S);
       // It is a compile-time error if `T` is `void`,
       // and `flatten(S)` is neither `void`, `dynamic`, nor `Null`.
       //
       // Note, the specification was not implemented correctly, and
       // implementing it now would be a breaking change. So, the code below
       // intentionally does not implement the specification.
       // https://github.com/dart-lang/sdk/issues/41803#issuecomment-635852474
       if (T.isVoid) {
         if (!_isVoidDynamicOrNull(flatten_S)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `flatten(S)` is `void`,
       // and `flatten(T)` is neither `void`, `dynamic`, nor `Null`.
       if (flatten_S.isVoid) {
         if (!_isVoidDynamicOrNull(flatten_T)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `flatten(S)` is not `void`,
       // and `Future<flatten(S)>` is not assignable to `T`.
       if (!flatten_S.isVoid) {
         var future_flatten_S = _typeProvider.futureType(flatten_S);
         if (!_typeSystem.isAssignableTo(future_flatten_S, T)) {
           reportTypeError();
           return;
         }
         // OK
         return;
       }
     }
   }

   void _checkReturnExpression_nullSafety(Expression expression) {
     // `T` is the declared return type.
     // `S` is the static type of the expression.
     var T = enclosingExecutable.returnType;
     var S = expression.typeOrThrow;

     void reportTypeError() {
       if (enclosingExecutable.catchErrorOnErrorReturnType != null) {
         _errorReporter.reportErrorForNode(
           HintCode.RETURN_OF_INVALID_TYPE_FROM_CATCH_ERROR,
           expression,
           [S, T],
         );
       } else if (enclosingExecutable.isClosure) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CLOSURE,
           expression,
           [S, T],
         );
       } else if (enclosingExecutable.isConstructor) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       } else if (enclosingExecutable.isFunction) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_FUNCTION,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       } else if (enclosingExecutable.isMethod) {
         _errorReporter.reportErrorForNode(
           CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_METHOD,
           expression,
           [S, T, enclosingExecutable.displayName],
         );
       }
     }

     if (enclosingExecutable.isSynchronous) {
       // It is a compile-time error if `T` is `void`,
       // and `S` is neither `void`, `dynamic`, nor `Null`.
       if (T.isVoid) {
         if (!_isVoidDynamicOrNull(S)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `S` is `void`,
       // and `T` is neither `void` nor `dynamic`.
       if (S.isVoid) {
         if (!_isVoidDynamic(T)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `S` is not `void`,
       // and `S` is not assignable to `T`.
       if (!S.isVoid) {
         if (!_typeSystem.isAssignableTo(S, T)) {
           reportTypeError();
           return;
         }
       }
       // OK
       return;
     }

     if (enclosingExecutable.isAsynchronous) {
       var T_v = _typeSystem.futureValueType(T);
       var flatten_S = _typeSystem.flatten(S);
       // It is a compile-time error if `flatten(T)` is `void`,
       // and `flatten(S)` is neither `void`, `dynamic`, nor `Null`.
       if (T_v.isVoid) {
         if (!_isVoidDynamicOrNull(flatten_S)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `flatten(S)` is `void`,
       // and `flatten(T)` is neither `void`, `dynamic`.
       if (flatten_S.isVoid) {
         if (!_isVoidDynamic(T_v)) {
           reportTypeError();
           return;
         }
       }
       // It is a compile-time error if `flatten(S)` is not `void`,
       // and `Future<flatten(S)>` is not assignable to `T`.
       if (!flatten_S.isVoid) {
         if (!_typeSystem.isAssignableTo(S, T_v) &&
             !_typeSystem.isSubtypeOf(flatten_S, T_v)) {
           reportTypeError();
           return;
         }
         // OK
         return;
       }
     }
   }

   void _checkReturnWithoutValue(ReturnStatement statement) {
     if (_typeSystem.isNonNullableByDefault) {
       var T = enclosingExecutable.returnType;
       if (enclosingExecutable.isSynchronous) {
         if (_isVoidDynamicOrNull(T)) {
           return;
         }
       } else {
         var T_v = _typeSystem.futureValueType(T);
         if (_isVoidDynamicOrNull(T_v)) {
           return;
         }
       }
     } else {
       var returnType = _flattenedReturnType;
       if (_isVoidDynamicOrNull(returnType)) {
         return;
       }
     }

     _errorReporter.reportErrorForToken(
       CompileTimeErrorCode.RETURN_WITHOUT_VALUE,
       statement.returnKeyword,
     );
   }

   bool _isLegalReturnType(ClassElement expectedElement) {
     DartType returnType = enclosingExecutable.returnType;
     //
     // When checking an async/sync*/async* method, we know the exact type
     // that will be returned (e.g. Future, Iterable, or Stream).
     //
     // For example an `async` function body will return a `Future<T>` for
     // some `T` (possibly `dynamic`).
     //
     // We allow the declared return type to be a supertype of that
     // (e.g. `dynamic`, `Object`), or Future<S> for some S.
     // (We assume the T <: S relation is checked elsewhere.)
     //
     // We do not allow user-defined subtypes of Future, because an `async`
     // method will never return those.
     //
     // To check for this, we ensure that `Future<bottom> <: returnType`.
     //
     // Similar logic applies for sync* and async*.
     //
     var lowerBound = expectedElement.instantiate(
       typeArguments: [NeverTypeImpl.instance],
       nullabilitySuffix: NullabilitySuffix.star,
     );
     return _typeSystem.isSubtypeOf(lowerBound, returnType);
   }

   static bool _isVoidDynamic(DartType type) {
     return type.isVoid || type.isDynamic;
   }

   static bool _isVoidDynamicOrNull(DartType type) {
     return type.isVoid || type.isDynamic || type.isDartCoreNull;
   }
 }
	// 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/nullability_suffix.dart';
	import 'package:analyzer/dart/element/type.dart';
	import 'package:analyzer/error/listener.dart';
	import 'package:analyzer/src/dart/ast/extensions.dart';
	import 'package:analyzer/src/dart/element/type.dart';
	import 'package:analyzer/src/dart/element/type_provider.dart';
	import 'package:analyzer/src/dart/element/type_system.dart';
	import 'package:analyzer/src/error/analyzer_error_code.dart';
	import 'package:analyzer/src/error/codes.dart';
	import 'package:analyzer/src/generated/error_verifier.dart';

	class ReturnTypeVerifier {
	final TypeProviderImpl _typeProvider;
	final TypeSystemImpl _typeSystem;
	final ErrorReporter _errorReporter;

	late EnclosingExecutableContext enclosingExecutable;

	ReturnTypeVerifier({
	required TypeProviderImpl typeProvider,
	required TypeSystemImpl typeSystem,
	required ErrorReporter errorReporter,
	}) : _typeProvider = typeProvider,
	_typeSystem = typeSystem,
	_errorReporter = errorReporter;

	DartType get _flattenedReturnType {
	var returnType = enclosingExecutable.returnType;
	if (enclosingExecutable.isSynchronous) {
	return returnType;
	} else {
	return _typeSystem.flatten(returnType);
	}
	}

	void verifyExpressionFunctionBody(ExpressionFunctionBody node) {
	// This enables concise declarations of void functions.
	if (_flattenedReturnType.isVoid) {
	return;
	}

	return _checkReturnExpression(node.expression);
	}

	void verifyReturnStatement(ReturnStatement statement) {
	var expression = statement.expression;

	if (enclosingExecutable.isGenerativeConstructor) {
	if (expression != null) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_IN_GENERATIVE_CONSTRUCTOR,
	expression,
	);
	}
	return;
	}

	if (enclosingExecutable.isGenerator) {
	return;
	}

	if (expression == null) {
	_checkReturnWithoutValue(statement);
	return;
	}

	_checkReturnExpression(expression);
	}

	void verifyReturnType(TypeAnnotation? returnType) {
	// If no declared type, then the type is `dynamic`, which is valid.
	if (returnType == null) {
	return;
	}

	void checkElement(
	ClassElement expectedElement,
	AnalyzerErrorCode errorCode,
	) {
	void reportError() {
	enclosingExecutable.hasLegalReturnType = false;
	_errorReporter.reportErrorForNode(errorCode, returnType);
	}

	// It is a compile-time error if the declared return type of
	// a function marked `sync` or `async` is `void`.
	if (enclosingExecutable.isGenerator) {
	if (enclosingExecutable.returnType.isVoid) {
	return reportError();
	}
	}

	// It is a compile-time error if the declared return type of
	// a function marked `...` is not a supertype of `...`.
	if (!_isLegalReturnType(expectedElement)) {
	return reportError();
	}
	}

	if (enclosingExecutable.isAsynchronous) {
	if (enclosingExecutable.isGenerator) {
	checkElement(
	_typeProvider.streamElement,
	CompileTimeErrorCode.ILLEGAL_ASYNC_GENERATOR_RETURN_TYPE,
	);
	} else {
	checkElement(
	_typeProvider.futureElement,
	CompileTimeErrorCode.ILLEGAL_ASYNC_RETURN_TYPE,
	);
	}
	} else if (enclosingExecutable.isGenerator) {
	checkElement(
	_typeProvider.iterableElement,
	CompileTimeErrorCode.ILLEGAL_SYNC_GENERATOR_RETURN_TYPE,
	);
	}
	}

	/// Check that a type mismatch between the type of the [expression] and
	/// the expected return type of the enclosing executable.
	void _checkReturnExpression(Expression expression) {
	if (!enclosingExecutable.hasLegalReturnType) {
	// ILLEGAL_ASYNC_RETURN_TYPE has already been reported, meaning the
	// _declared_ return type is illegal; don't confuse by also reporting
	// that the type being returned here does not match that illegal return
	// type.
	return;
	}

	if (_typeSystem.isNonNullableByDefault) {
	_checkReturnExpression_nullSafety(expression);
	} else {
	_checkReturnExpression_legacy(expression);
	}
	}

	void _checkReturnExpression_legacy(Expression expression) {
	// `T` is the declared return type.
	// `S` is the static type of the expression.
	var T = enclosingExecutable.returnType;
	var S = expression.typeOrThrow;

	void reportTypeError() {
	if (enclosingExecutable.catchErrorOnErrorReturnType != null) {
	_errorReporter.reportErrorForNode(
	HintCode.RETURN_OF_INVALID_TYPE_FROM_CATCH_ERROR,
	expression,
	[S, T],
	);
	} else if (enclosingExecutable.isClosure) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CLOSURE,
	expression,
	[S, T],
	);
	} else if (enclosingExecutable.isConstructor) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	} else if (enclosingExecutable.isFunction) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_FUNCTION,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	} else if (enclosingExecutable.isMethod) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_METHOD,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	}
	}

	if (enclosingExecutable.isSynchronous) {
	// It is a compile-time error if `T` is `void`,
	// and `S` is neither `void`, `dynamic`, nor `Null`.
	if (T.isVoid) {
	if (!_isVoidDynamicOrNull(S)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `S` is `void`,
	// and `T` is neither `void`, `dynamic`, nor `Null`.
	if (S.isVoid) {
	if (!_isVoidDynamicOrNull(T)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `S` is not `void`,
	// and `S` is not assignable to `T`.
	if (!S.isVoid) {
	if (!_typeSystem.isAssignableTo(S, T)) {
	reportTypeError();
	return;
	}
	}
	// OK
	return;
	}

	if (enclosingExecutable.isAsynchronous) {
	var flatten_T = _typeSystem.flatten(T);
	var flatten_S = _typeSystem.flatten(S);
	// It is a compile-time error if `T` is `void`,
	// and `flatten(S)` is neither `void`, `dynamic`, nor `Null`.
	//
	// Note, the specification was not implemented correctly, and
	// implementing it now would be a breaking change. So, the code below
	// intentionally does not implement the specification.
	// https://github.com/dart-lang/sdk/issues/41803#issuecomment-635852474
	if (T.isVoid) {
	if (!_isVoidDynamicOrNull(flatten_S)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `flatten(S)` is `void`,
	// and `flatten(T)` is neither `void`, `dynamic`, nor `Null`.
	if (flatten_S.isVoid) {
	if (!_isVoidDynamicOrNull(flatten_T)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `flatten(S)` is not `void`,
	// and `Future<flatten(S)>` is not assignable to `T`.
	if (!flatten_S.isVoid) {
	var future_flatten_S = _typeProvider.futureType(flatten_S);
	if (!_typeSystem.isAssignableTo(future_flatten_S, T)) {
	reportTypeError();
	return;
	}
	// OK
	return;
	}
	}
	}

	void _checkReturnExpression_nullSafety(Expression expression) {
	// `T` is the declared return type.
	// `S` is the static type of the expression.
	var T = enclosingExecutable.returnType;
	var S = expression.typeOrThrow;

	void reportTypeError() {
	if (enclosingExecutable.catchErrorOnErrorReturnType != null) {
	_errorReporter.reportErrorForNode(
	HintCode.RETURN_OF_INVALID_TYPE_FROM_CATCH_ERROR,
	expression,
	[S, T],
	);
	} else if (enclosingExecutable.isClosure) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CLOSURE,
	expression,
	[S, T],
	);
	} else if (enclosingExecutable.isConstructor) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	} else if (enclosingExecutable.isFunction) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_FUNCTION,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	} else if (enclosingExecutable.isMethod) {
	_errorReporter.reportErrorForNode(
	CompileTimeErrorCode.RETURN_OF_INVALID_TYPE_FROM_METHOD,
	expression,
	[S, T, enclosingExecutable.displayName],
	);
	}
	}

	if (enclosingExecutable.isSynchronous) {
	// It is a compile-time error if `T` is `void`,
	// and `S` is neither `void`, `dynamic`, nor `Null`.
	if (T.isVoid) {
	if (!_isVoidDynamicOrNull(S)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `S` is `void`,
	// and `T` is neither `void` nor `dynamic`.
	if (S.isVoid) {
	if (!_isVoidDynamic(T)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `S` is not `void`,
	// and `S` is not assignable to `T`.
	if (!S.isVoid) {
	if (!_typeSystem.isAssignableTo(S, T)) {
	reportTypeError();
	return;
	}
	}
	// OK
	return;
	}

	if (enclosingExecutable.isAsynchronous) {
	var T_v = _typeSystem.futureValueType(T);
	var flatten_S = _typeSystem.flatten(S);
	// It is a compile-time error if `flatten(T)` is `void`,
	// and `flatten(S)` is neither `void`, `dynamic`, nor `Null`.
	if (T_v.isVoid) {
	if (!_isVoidDynamicOrNull(flatten_S)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `flatten(S)` is `void`,
	// and `flatten(T)` is neither `void`, `dynamic`.
	if (flatten_S.isVoid) {
	if (!_isVoidDynamic(T_v)) {
	reportTypeError();
	return;
	}
	}
	// It is a compile-time error if `flatten(S)` is not `void`,
	// and `Future<flatten(S)>` is not assignable to `T`.
	if (!flatten_S.isVoid) {
	if (!_typeSystem.isAssignableTo(S, T_v) &&
	!_typeSystem.isSubtypeOf(flatten_S, T_v)) {
	reportTypeError();
	return;
	}
	// OK
	return;
	}
	}
	}

	void _checkReturnWithoutValue(ReturnStatement statement) {
	if (_typeSystem.isNonNullableByDefault) {
	var T = enclosingExecutable.returnType;
	if (enclosingExecutable.isSynchronous) {
	if (_isVoidDynamicOrNull(T)) {
	return;
	}
	} else {
	var T_v = _typeSystem.futureValueType(T);
	if (_isVoidDynamicOrNull(T_v)) {
	return;
	}
	}
	} else {
	var returnType = _flattenedReturnType;
	if (_isVoidDynamicOrNull(returnType)) {
	return;
	}
	}

	_errorReporter.reportErrorForToken(
	CompileTimeErrorCode.RETURN_WITHOUT_VALUE,
	statement.returnKeyword,
	);
	}

	bool _isLegalReturnType(ClassElement expectedElement) {
	DartType returnType = enclosingExecutable.returnType;
	//
	// When checking an async/sync/async method, we know the exact type
	// that will be returned (e.g. Future, Iterable, or Stream).
	//
	// For example an `async` function body will return a `Future<T>` for
	// some `T` (possibly `dynamic`).
	//
	// We allow the declared return type to be a supertype of that
	// (e.g. `dynamic`, `Object`), or Future<S> for some S.
	// (We assume the T <: S relation is checked elsewhere.)
	//
	// We do not allow user-defined subtypes of Future, because an `async`
	// method will never return those.
	//
	// To check for this, we ensure that `Future<bottom> <: returnType`.
	//
	// Similar logic applies for sync* and async*.
	//
	var lowerBound = expectedElement.instantiate(
	typeArguments: [NeverTypeImpl.instance],
	nullabilitySuffix: NullabilitySuffix.star,
	);
	return _typeSystem.isSubtypeOf(lowerBound, returnType);
	}

	static bool _isVoidDynamic(DartType type) {
	return type.isVoid \|\| type.isDynamic;
	}

	static bool _isVoidDynamicOrNull(DartType type) {
	return type.isVoid \|\| type.isDynamic \|\| type.isDartCoreNull;
	}
	}