Exemplo n.º 1
0
            internal SubmissionEntryPoint(NamedTypeSymbol containingType, TypeWithAnnotations returnType, TypeSymbol submissionArrayType) :
                base(containingType)
            {
                Debug.Assert(containingType.IsSubmissionClass);
                Debug.Assert(!returnType.IsVoidType());
                _parameters = ImmutableArray.Create(SynthesizedParameterSymbol.Create(this,
                                                                                      TypeWithAnnotations.Create(submissionArrayType), 0, RefKind.None, "submissionArray"));

                _returnType = returnType;
            }
Exemplo n.º 2
0
            // private static T <Factory>(object[] submissionArray)
            // {
            //     var submission = new Submission#N(submissionArray);
            //     return submission.<Initialize>();
            // }
            internal override BoundBlock CreateBody(DiagnosticBag diagnostics)
            {
                var syntax = DummySyntax();

                var ctor = _containingType.GetScriptConstructor();

                Debug.Assert(ctor.ParameterCount == 1);

                var initializer = _containingType.GetScriptInitializer();

                Debug.Assert(initializer.ParameterCount == 0);

                var submissionArrayParameter = new BoundParameter(syntax, _parameters[0])
                {
                    WasCompilerGenerated = true
                };
                var submissionLocal = new BoundLocal(
                    syntax,
                    new SynthesizedLocal(this, TypeWithAnnotations.Create(_containingType), SynthesizedLocalKind.LoweringTemp),
                    null,
                    _containingType)
                {
                    WasCompilerGenerated = true
                };

                // var submission = new Submission#N(submissionArray);
                var submissionAssignment = new BoundExpressionStatement(
                    syntax,
                    new BoundAssignmentOperator(
                        syntax,
                        submissionLocal,
                        new BoundObjectCreationExpression(
                            syntax,
                            ctor,
                            ImmutableArray.Create <BoundExpression>(submissionArrayParameter),
                            default(ImmutableArray <string>),
                            default(ImmutableArray <RefKind>),
                            false,
                            default(ImmutableArray <int>),
                            null,
                            null,
                            null,
                            _containingType)
                {
                    WasCompilerGenerated = true
                },
                        _containingType)
                {
                    WasCompilerGenerated = true
                })
                {
                    WasCompilerGenerated = true
                };

                // return submission.<Initialize>();
                var initializeResult = CreateParameterlessCall(
                    syntax,
                    submissionLocal,
                    initializer);

                Debug.Assert(TypeSymbol.Equals(initializeResult.Type, _returnType.Type, TypeCompareKind.ConsiderEverything2));
                var returnStatement = new BoundReturnStatement(
                    syntax,
                    RefKind.None,
                    initializeResult)
                {
                    WasCompilerGenerated = true
                };

                return(new BoundBlock(syntax,
                                      ImmutableArray.Create <LocalSymbol>(submissionLocal.LocalSymbol),
                                      ImmutableArray.Create <BoundStatement>(submissionAssignment, returnStatement))
                {
                    WasCompilerGenerated = true
                });
            }
Exemplo n.º 3
0
        /// <summary>
        /// Resolves <see cref="System.Type"/> to a <see cref="TypeSymbol"/> available in this assembly
        /// its referenced assemblies.
        /// </summary>
        /// <param name="type">The type to resolve.</param>
        /// <param name="includeReferences">Use referenced assemblies for resolution.</param>
        /// <returns>The resolved symbol if successful or null on failure.</returns>
        internal TypeSymbol GetTypeByReflectionType(Type type, bool includeReferences)
        {
            System.Reflection.TypeInfo typeInfo = type.GetTypeInfo();

            Debug.Assert(!typeInfo.IsByRef);

            // not supported (we don't accept open types as submission results nor host types):
            Debug.Assert(!typeInfo.ContainsGenericParameters);

            if (typeInfo.IsArray)
            {
                TypeSymbol symbol = GetTypeByReflectionType(typeInfo.GetElementType(), includeReferences);
                if ((object)symbol == null)
                {
                    return(null);
                }

                int rank = typeInfo.GetArrayRank();

                return(ArrayTypeSymbol.CreateCSharpArray(this, TypeWithAnnotations.Create(symbol), rank));
            }
            else if (typeInfo.IsPointer)
            {
                TypeSymbol symbol = GetTypeByReflectionType(typeInfo.GetElementType(), includeReferences);
                if ((object)symbol == null)
                {
                    return(null);
                }

                return(new PointerTypeSymbol(TypeWithAnnotations.Create(symbol)));
            }
            else if (typeInfo.DeclaringType != null)
            {
                Debug.Assert(!typeInfo.IsArray);

                // consolidated generic arguments (includes arguments of all declaring types):
                Type[] genericArguments  = typeInfo.GenericTypeArguments;
                int    typeArgumentIndex = 0;

                var currentTypeInfo = typeInfo.IsGenericType ? typeInfo.GetGenericTypeDefinition().GetTypeInfo() : typeInfo;
                var nestedTypes     = ArrayBuilder <System.Reflection.TypeInfo> .GetInstance();

                while (true)
                {
                    Debug.Assert(currentTypeInfo.IsGenericTypeDefinition || !currentTypeInfo.IsGenericType);

                    nestedTypes.Add(currentTypeInfo);
                    if (currentTypeInfo.DeclaringType == null)
                    {
                        break;
                    }

                    currentTypeInfo = currentTypeInfo.DeclaringType.GetTypeInfo();
                }

                int i      = nestedTypes.Count - 1;
                var symbol = (NamedTypeSymbol)GetTypeByReflectionType(nestedTypes[i].AsType(), includeReferences);
                if ((object)symbol == null)
                {
                    return(null);
                }

                while (--i >= 0)
                {
                    int forcedArity         = nestedTypes[i].GenericTypeParameters.Length - nestedTypes[i + 1].GenericTypeParameters.Length;
                    MetadataTypeName mdName = MetadataTypeName.FromTypeName(nestedTypes[i].Name, forcedArity: forcedArity);

                    symbol = symbol.LookupMetadataType(ref mdName);
                    if ((object)symbol == null || symbol.IsErrorType())
                    {
                        return(null);
                    }

                    symbol = ApplyGenericArguments(symbol, genericArguments, ref typeArgumentIndex, includeReferences);
                    if ((object)symbol == null)
                    {
                        return(null);
                    }
                }

                nestedTypes.Free();
                Debug.Assert(typeArgumentIndex == genericArguments.Length);
                return(symbol);
            }
            else
            {
                AssemblyIdentity assemblyId = AssemblyIdentity.FromAssemblyDefinition(typeInfo.Assembly);

                MetadataTypeName mdName = MetadataTypeName.FromNamespaceAndTypeName(
                    typeInfo.Namespace ?? string.Empty,
                    typeInfo.Name,
                    forcedArity: typeInfo.GenericTypeArguments.Length);

                NamedTypeSymbol symbol = GetTopLevelTypeByMetadataName(ref mdName, assemblyId, includeReferences, isWellKnownType: false, conflicts: out var _);

                if ((object)symbol == null || symbol.IsErrorType())
                {
                    return(null);
                }

                int    typeArgumentIndex = 0;
                Type[] genericArguments  = typeInfo.GenericTypeArguments;
                symbol = ApplyGenericArguments(symbol, genericArguments, ref typeArgumentIndex, includeReferences);
                Debug.Assert(typeArgumentIndex == genericArguments.Length);
                return(symbol);
            }
        }
Exemplo n.º 4
0
            // private static void <Main>()
            // {
            //     var script = new Script();
            //     script.<Initialize>().GetAwaiter().GetResult();
            // }
            internal override BoundBlock CreateBody(DiagnosticBag diagnostics)
            {
                var syntax      = DummySyntax();
                var compilation = _containingType.DeclaringCompilation;

                // Creates a new top-level binder that just contains the global imports for the compilation.
                // The imports are required if a consumer of the scripting API is using a Task implementation
                // that uses extension methods.
                var binder = new InContainerBinder(
                    container: null,
                    next: new BuckStopsHereBinder(compilation),
                    imports: compilation.GlobalImports);

                binder = new InContainerBinder(compilation.GlobalNamespace, binder);

                var ctor = _containingType.GetScriptConstructor();

                Debug.Assert(ctor.ParameterCount == 0);

                var initializer = _containingType.GetScriptInitializer();

                Debug.Assert(initializer.ParameterCount == 0);

                var scriptLocal = new BoundLocal(
                    syntax,
                    new SynthesizedLocal(this, TypeWithAnnotations.Create(_containingType), SynthesizedLocalKind.LoweringTemp),
                    null,
                    _containingType)
                {
                    WasCompilerGenerated = true
                };

                Debug.Assert(!initializer.ReturnType.IsDynamic());
                var             initializeCall = CreateParameterlessCall(syntax, scriptLocal, initializer);
                BoundExpression getAwaiterGetResultCall;

                if (!binder.GetAwaitableExpressionInfo(initializeCall, out getAwaiterGetResultCall, syntax, diagnostics))
                {
                    return(new BoundBlock(
                               syntax: syntax,
                               locals: ImmutableArray <LocalSymbol> .Empty,
                               statements: ImmutableArray <BoundStatement> .Empty,
                               hasErrors: true));
                }

                return(new BoundBlock(syntax,
                                      ImmutableArray.Create <LocalSymbol>(scriptLocal.LocalSymbol),
                                      ImmutableArray.Create <BoundStatement>(
                                          // var script = new Script();
                                          new BoundExpressionStatement(
                                              syntax,
                                              new BoundAssignmentOperator(
                                                  syntax,
                                                  scriptLocal,
                                                  new BoundObjectCreationExpression(
                                                      syntax,
                                                      ctor,
                                                      null)
                {
                    WasCompilerGenerated = true
                },
                                                  _containingType)
                {
                    WasCompilerGenerated = true
                })
                {
                    WasCompilerGenerated = true
                },
                                          // script.<Initialize>().GetAwaiter().GetResult();
                                          new BoundExpressionStatement(syntax, getAwaiterGetResultCall)
                {
                    WasCompilerGenerated = true
                },
                                          // return;
                                          new BoundReturnStatement(
                                              syntax,
                                              RefKind.None,
                                              null)
                {
                    WasCompilerGenerated = true
                }))
                {
                    WasCompilerGenerated = true
                });
            }
Exemplo n.º 5
0
            protected override TypeWithAnnotations InferTypeOfVarVariable(BindingDiagnosticBag diagnostics)
            {
                BoundExpression initializerOpt = this._initializerBinder.BindInferredVariableInitializer(diagnostics, RefKind, _initializer, _initializer);

                return(TypeWithAnnotations.Create(initializerOpt?.Type));
            }
Exemplo n.º 6
0
        internal sealed override TypeWithAnnotations GetFieldType(ConsList <FieldSymbol> fieldsBeingBound)
        {
            Debug.Assert(fieldsBeingBound != null);

            if (!_lazyType.IsDefault)
            {
                return(_lazyType.ToType());
            }

            var declarator  = VariableDeclaratorNode;
            var fieldSyntax = GetFieldDeclaration(declarator);
            var typeSyntax  = fieldSyntax.Declaration.Type;

            var compilation = this.DeclaringCompilation;

            var diagnostics = DiagnosticBag.GetInstance();
            TypeWithAnnotations type;

            // When we have multiple declarators, we report the type diagnostics on only the first.
            DiagnosticBag diagnosticsForFirstDeclarator = DiagnosticBag.GetInstance();

            Symbol associatedPropertyOrEvent = this.AssociatedSymbol;

            if ((object)associatedPropertyOrEvent != null && associatedPropertyOrEvent.Kind == SymbolKind.Event)
            {
                EventSymbol @event = (EventSymbol)associatedPropertyOrEvent;
                if (@event.IsWindowsRuntimeEvent)
                {
                    NamedTypeSymbol tokenTableType = this.DeclaringCompilation.GetWellKnownType(WellKnownType.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T);
                    Binder.ReportUseSiteDiagnostics(tokenTableType, diagnosticsForFirstDeclarator, this.ErrorLocation);

                    // CONSIDER: Do we want to guard against the possibility that someone has created their own EventRegistrationTokenTable<T>
                    // type that has additional generic constraints?
                    type = TypeWithAnnotations.Create(tokenTableType.Construct(ImmutableArray.Create(@event.TypeWithAnnotations)));
                }
                else
                {
                    type = @event.TypeWithAnnotations;
                }
            }
            else
            {
                var binderFactory = compilation.GetBinderFactory(SyntaxTree);
                var binder        = binderFactory.GetBinder(typeSyntax);

                binder = binder.WithAdditionalFlagsAndContainingMemberOrLambda(BinderFlags.SuppressConstraintChecks, this);
                if (!ContainingType.IsScriptClass)
                {
                    type = binder.BindType(typeSyntax, diagnosticsForFirstDeclarator);
                }
                else
                {
                    bool isVar;
                    type = binder.BindTypeOrVarKeyword(typeSyntax, diagnostics, out isVar);

                    Debug.Assert(type.HasType || isVar);

                    if (isVar)
                    {
                        if (this.IsConst)
                        {
                            diagnosticsForFirstDeclarator.Add(ErrorCode.ERR_ImplicitlyTypedVariableCannotBeConst, typeSyntax.Location);
                        }

                        if (fieldsBeingBound.ContainsReference(this))
                        {
                            diagnostics.Add(ErrorCode.ERR_RecursivelyTypedVariable, this.ErrorLocation, this);
                            type = default;
                        }
                        else if (fieldSyntax.Declaration.Variables.Count > 1)
                        {
                            diagnosticsForFirstDeclarator.Add(ErrorCode.ERR_ImplicitlyTypedVariableMultipleDeclarator, typeSyntax.Location);
                        }
                        else if (this.IsConst && this.ContainingType.IsScriptClass)
                        {
                            // For const var in script, we won't try to bind the initializer (case below), as it can lead to an unbound recursion
                            type = default;
                        }
                        else
                        {
                            fieldsBeingBound = new ConsList <FieldSymbol>(this, fieldsBeingBound);

                            var initializerBinder = new ImplicitlyTypedFieldBinder(binder, fieldsBeingBound);
                            var initializerOpt    = initializerBinder.BindInferredVariableInitializer(diagnostics, RefKind.None, (EqualsValueClauseSyntax)declarator.Initializer, declarator);

                            if (initializerOpt != null)
                            {
                                if ((object)initializerOpt.Type != null && !initializerOpt.Type.IsErrorType())
                                {
                                    type = TypeWithAnnotations.Create(initializerOpt.Type);
                                }

                                _lazyFieldTypeInferred = 1;
                            }
                        }

                        if (!type.HasType)
                        {
                            type = TypeWithAnnotations.Create(binder.CreateErrorType("var"));
                        }
                    }
                }

                if (IsFixedSizeBuffer)
                {
                    type = TypeWithAnnotations.Create(new PointerTypeSymbol(type));

                    if (ContainingType.TypeKind != TypeKind.Struct)
                    {
                        diagnostics.Add(ErrorCode.ERR_FixedNotInStruct, ErrorLocation);
                    }

                    var elementType = ((PointerTypeSymbol)type.Type).PointedAtType;
                    int elementSize = elementType.FixedBufferElementSizeInBytes();
                    if (elementSize == 0)
                    {
                        var loc = typeSyntax.Location;
                        diagnostics.Add(ErrorCode.ERR_IllegalFixedType, loc);
                    }

                    if (!binder.InUnsafeRegion)
                    {
                        diagnosticsForFirstDeclarator.Add(ErrorCode.ERR_UnsafeNeeded, declarator.Location);
                    }
                }
            }

            // update the lazyType only if it contains value last seen by the current thread:
            if (_lazyType.InterlockedInitialize(type.WithModifiers(this.RequiredCustomModifiers)))
            {
                TypeChecks(type.Type, diagnostics);

                // CONSIDER: SourceEventFieldSymbol would like to suppress these diagnostics.
                compilation.DeclarationDiagnostics.AddRange(diagnostics);

                bool isFirstDeclarator = fieldSyntax.Declaration.Variables[0] == declarator;
                if (isFirstDeclarator)
                {
                    compilation.DeclarationDiagnostics.AddRange(diagnosticsForFirstDeclarator);
                }

                state.NotePartComplete(CompletionPart.Type);
            }

            diagnostics.Free();
            diagnosticsForFirstDeclarator.Free();
            return(_lazyType.ToType());
        }
Exemplo n.º 7
0
 protected virtual TypeWithAnnotations SubstituteTypeParameter(TypeParameterSymbol typeParameter)
 {
     return TypeWithAnnotations.Create(typeParameter);
 }
Exemplo n.º 8
0
 /// <summary>
 /// Called by <see cref="AbstractTypeMap.SubstituteType(TypeSymbol)"/> to perform substitution
 /// on types with TypeKind ErrorType.  The general pattern is to use the type map
 /// to perform substitution on the wrapped type, if any, and then construct a new
 /// error type symbol from the result (if there was a change).
 /// </summary>
 internal TypeWithAnnotations Substitute(AbstractTypeMap typeMap)
 {
     return(TypeWithAnnotations.Create(typeMap.SubstituteNamedType(this)));
 }
Exemplo n.º 9
0
        /// <summary>
        /// If the extension method is applicable based on the "this" argument type, return
        /// the method constructed with the inferred type arguments. If the method is not an
        /// unconstructed generic method, type inference is skipped. If the method is not
        /// applicable, or if constraints when inferring type parameters from the "this" type
        /// are not satisfied, the return value is null.
        /// </summary>
        /// <param name="compilation">Compilation used to check constraints.  The latest language version is assumed if this is null.</param>
        private static MethodSymbol InferExtensionMethodTypeArguments(MethodSymbol method, TypeSymbol thisType, CSharpCompilation compilation, ref HashSet <DiagnosticInfo> useSiteDiagnostics)
        {
            Debug.Assert(method.IsExtensionMethod);
            Debug.Assert((object)thisType != null);

            if (!method.IsGenericMethod || method != method.ConstructedFrom)
            {
                return(method);
            }

            // We never resolve extension methods on a dynamic receiver.
            if (thisType.IsDynamic())
            {
                return(null);
            }

            var containingAssembly = method.ContainingAssembly;
            var errorNamespace     = containingAssembly.GlobalNamespace;
            var conversions        = new TypeConversions(containingAssembly.CorLibrary);

            // There is absolutely no plausible syntax/tree that we could use for these
            // synthesized literals.  We could be speculatively binding a call to a PE method.
            var syntaxTree = CSharpSyntaxTree.Dummy;
            var syntax     = (CSharpSyntaxNode)syntaxTree.GetRoot();

            // Create an argument value for the "this" argument of specific type,
            // and pass the same bad argument value for all other arguments.
            var thisArgumentValue = new BoundLiteral(syntax, ConstantValue.Bad, thisType)
            {
                WasCompilerGenerated = true
            };
            var otherArgumentType  = new ExtendedErrorTypeSymbol(errorNamespace, name: string.Empty, arity: 0, errorInfo: null, unreported: false);
            var otherArgumentValue = new BoundLiteral(syntax, ConstantValue.Bad, otherArgumentType)
            {
                WasCompilerGenerated = true
            };

            var paramCount = method.ParameterCount;
            var arguments  = new BoundExpression[paramCount];

            for (int i = 0; i < paramCount; i++)
            {
                var argument = (i == 0) ? thisArgumentValue : otherArgumentValue;
                arguments[i] = argument;
            }

            var typeArgs = MethodTypeInferrer.InferTypeArgumentsFromFirstArgument(
                conversions,
                method,
                arguments.AsImmutable(),
                useSiteDiagnostics: ref useSiteDiagnostics);

            if (typeArgs.IsDefault)
            {
                return(null);
            }

            // For the purpose of constraint checks we use error type symbol in place of type arguments that we couldn't infer from the first argument.
            // This prevents constraint checking from failing for corresponding type parameters.
            int firstNullInTypeArgs       = -1;
            var notInferredTypeParameters = PooledHashSet <TypeParameterSymbol> .GetInstance();

            var typeParams = method.TypeParameters;
            var typeArgsForConstraintsCheck = typeArgs;

            for (int i = 0; i < typeArgsForConstraintsCheck.Length; i++)
            {
                if (!typeArgsForConstraintsCheck[i].HasType)
                {
                    firstNullInTypeArgs = i;
                    var builder = ArrayBuilder <TypeWithAnnotations> .GetInstance();

                    builder.AddRange(typeArgsForConstraintsCheck, firstNullInTypeArgs);

                    for (; i < typeArgsForConstraintsCheck.Length; i++)
                    {
                        var typeArg = typeArgsForConstraintsCheck[i];
                        if (!typeArg.HasType)
                        {
                            notInferredTypeParameters.Add(typeParams[i]);
                            builder.Add(TypeWithAnnotations.Create(ErrorTypeSymbol.UnknownResultType));
                        }
                        else
                        {
                            builder.Add(typeArg);
                        }
                    }

                    typeArgsForConstraintsCheck = builder.ToImmutableAndFree();
                    break;
                }
            }

            // Check constraints.
            var diagnosticsBuilder = ArrayBuilder <TypeParameterDiagnosticInfo> .GetInstance();

            var substitution = new TypeMap(typeParams, typeArgsForConstraintsCheck);
            ArrayBuilder <TypeParameterDiagnosticInfo> useSiteDiagnosticsBuilder = null;
            var success = method.CheckConstraints(conversions, substitution, typeParams, typeArgsForConstraintsCheck, compilation, diagnosticsBuilder, nullabilityDiagnosticsBuilderOpt: null, ref useSiteDiagnosticsBuilder,
                                                  ignoreTypeConstraintsDependentOnTypeParametersOpt: notInferredTypeParameters.Count > 0 ? notInferredTypeParameters : null);

            diagnosticsBuilder.Free();
            notInferredTypeParameters.Free();

            if (useSiteDiagnosticsBuilder != null && useSiteDiagnosticsBuilder.Count > 0)
            {
                if (useSiteDiagnostics == null)
                {
                    useSiteDiagnostics = new HashSet <DiagnosticInfo>();
                }

                foreach (var diag in useSiteDiagnosticsBuilder)
                {
                    useSiteDiagnostics.Add(diag.DiagnosticInfo);
                }
            }

            if (!success)
            {
                return(null);
            }

            // For the purpose of construction we use original type parameters in place of type arguments that we couldn't infer from the first argument.
            ImmutableArray <TypeWithAnnotations> typeArgsForConstruct = typeArgs;

            if (typeArgs.Any(t => !t.HasType))
            {
                typeArgsForConstruct = typeArgs.ZipAsArray(
                    method.TypeParameters,
                    (t, tp) => t.HasType ? t : TypeWithAnnotations.Create(tp));
            }

            return(method.Construct(typeArgsForConstruct));
        }
        internal static void AddDelegateMembers(
            SourceMemberContainerTypeSymbol delegateType,
            ArrayBuilder <Symbol> symbols,
            DelegateDeclarationSyntax syntax,
            DiagnosticBag diagnostics)
        {
            var        compilation = delegateType.DeclaringCompilation;
            Binder     binder      = delegateType.GetBinder(syntax.ParameterList);
            RefKind    refKind;
            TypeSyntax returnTypeSyntax = syntax.ReturnType.SkipRef(out refKind);
            var        returnType       = binder.BindType(returnTypeSyntax, diagnostics);

            // reuse types to avoid reporting duplicate errors if missing:
            var voidType = TypeWithAnnotations.Create(binder.GetSpecialType(SpecialType.System_Void, diagnostics, syntax));
            // https://github.com/dotnet/roslyn/issues/30079: Should the 'object', IAsyncResult and AsyncCallback parameters be considered nullable or not nullable?
            var objectType = TypeWithAnnotations.Create(binder.GetSpecialType(SpecialType.System_Object, diagnostics, syntax));
            var intPtrType = TypeWithAnnotations.Create(binder.GetSpecialType(SpecialType.System_IntPtr, diagnostics, syntax));

            if (returnType.IsRestrictedType(ignoreSpanLikeTypes: true))
            {
                // The return type of a method, delegate, or function pointer cannot be '{0}'
                diagnostics.Add(ErrorCode.ERR_MethodReturnCantBeRefAny, returnTypeSyntax.Location, returnType.Type);
            }

            // A delegate has the following members: (see CLI spec 13.6)
            // (1) a method named Invoke with the specified signature
            var invoke = new InvokeMethod(delegateType, refKind, returnType, syntax, binder, diagnostics);

            invoke.CheckDelegateVarianceSafety(diagnostics);
            symbols.Add(invoke);

            // (2) a constructor with argument types (object, System.IntPtr)
            symbols.Add(new Constructor(delegateType, voidType, objectType, intPtrType, syntax));

            if (binder.Compilation.GetSpecialType(SpecialType.System_IAsyncResult).TypeKind != TypeKind.Error &&
                binder.Compilation.GetSpecialType(SpecialType.System_AsyncCallback).TypeKind != TypeKind.Error &&
                // WinRT delegates don't have Begin/EndInvoke methods
                !delegateType.IsCompilationOutputWinMdObj())
            {
                var iAsyncResultType  = TypeWithAnnotations.Create(binder.GetSpecialType(SpecialType.System_IAsyncResult, diagnostics, syntax));
                var asyncCallbackType = TypeWithAnnotations.Create(binder.GetSpecialType(SpecialType.System_AsyncCallback, diagnostics, syntax));

                // (3) BeginInvoke
                symbols.Add(new BeginInvokeMethod(invoke, iAsyncResultType, objectType, asyncCallbackType, syntax));

                // and (4) EndInvoke methods
                symbols.Add(new EndInvokeMethod(invoke, iAsyncResultType, syntax));
            }

            if (delegateType.DeclaredAccessibility <= Accessibility.Private)
            {
                return;
            }

            HashSet <DiagnosticInfo> useSiteDiagnostics = null;

            if (!delegateType.IsNoMoreVisibleThan(invoke.ReturnTypeWithAnnotations, ref useSiteDiagnostics))
            {
                // Inconsistent accessibility: return type '{1}' is less accessible than delegate '{0}'
                diagnostics.Add(ErrorCode.ERR_BadVisDelegateReturn, delegateType.Locations[0], delegateType, invoke.ReturnType);
            }

            foreach (var parameter in invoke.Parameters)
            {
                if (!parameter.TypeWithAnnotations.IsAtLeastAsVisibleAs(delegateType, ref useSiteDiagnostics))
                {
                    // Inconsistent accessibility: parameter type '{1}' is less accessible than delegate '{0}'
                    diagnostics.Add(ErrorCode.ERR_BadVisDelegateParam, delegateType.Locations[0], delegateType, parameter.Type);
                }
            }

            diagnostics.Add(delegateType.Locations[0], useSiteDiagnostics);
        }
Exemplo n.º 11
0
 internal override TypeWithAnnotations GetFieldType(ConsList <FieldSymbol> fieldsBeingBound)
 {
     return(TypeWithAnnotations.Create(this.ContainingType));
 }
 internal override TypeWithAnnotations GetFieldType(ConsList <FieldSymbol> fieldsBeingBound)
 {
     return(TypeWithAnnotations.Create(((SourceNamedTypeSymbol)ContainingType).EnumUnderlyingType));
 }
Exemplo n.º 13
0
 internal AnonymousTypeEqualsMethodSymbol(NamedTypeSymbol container)
     : base(container, WellKnownMemberNames.ObjectEquals)
 {
     _parameters = ImmutableArray.Create <ParameterSymbol>(
         SynthesizedParameterSymbol.Create(this, TypeWithAnnotations.Create(this.Manager.System_Object), 0, RefKind.None, "value"));
 }
Exemplo n.º 14
0
 // https://github.com/dotnet/roslyn/issues/30071: Replace with Construct(ImmutableArray<TypeWithAnnotations>).
 /// <summary>
 /// Apply type substitution to a generic method to create an method symbol with the given type parameters supplied.
 /// </summary>
 /// <param name="typeArguments"></param>
 /// <returns></returns>
 public MethodSymbol Construct(ImmutableArray <TypeSymbol> typeArguments)
 {
     return(Construct(typeArguments.SelectAsArray(a => TypeWithAnnotations.Create(a))));
 }
 internal SynthesizedThrowMethod(SourceModuleSymbol containingModule, PrivateImplementationDetails privateImplType, TypeSymbol returnType, TypeSymbol paramType)
     : base(containingModule, privateImplType, returnType, PrivateImplementationDetails.SynthesizedThrowFunctionName)
 {
     this.SetParameters(ImmutableArray.Create <ParameterSymbol>(SynthesizedParameterSymbol.Create(this, TypeWithAnnotations.Create(paramType), 0, RefKind.None, "paramName")));
 }
            internal AnonymousTypeTemplateSymbol(AnonymousTypeManager manager, AnonymousTypeDescriptor typeDescr) :
                base(manager, typeDescr.Location)
            {
                this.TypeDescriptorKey = typeDescr.Key;

                int fieldsCount  = typeDescr.Fields.Length;
                int membersCount = fieldsCount * 3 + 1;

                // members
                var membersBuilder = ArrayBuilder <Symbol> .GetInstance(membersCount);

                var propertiesBuilder = ArrayBuilder <AnonymousTypePropertySymbol> .GetInstance(fieldsCount);

                var typeParametersBuilder = ArrayBuilder <TypeParameterSymbol> .GetInstance(fieldsCount);

                // Process fields
                for (int fieldIndex = 0; fieldIndex < fieldsCount; fieldIndex++)
                {
                    AnonymousTypeField field = typeDescr.Fields[fieldIndex];

                    // Add a type parameter
                    AnonymousTypeParameterSymbol typeParameter =
                        new AnonymousTypeParameterSymbol(this, fieldIndex, GeneratedNames.MakeAnonymousTypeParameterName(field.Name));
                    typeParametersBuilder.Add(typeParameter);

                    // Add a property
                    AnonymousTypePropertySymbol property = new AnonymousTypePropertySymbol(this, field, TypeWithAnnotations.Create(typeParameter), fieldIndex);
                    propertiesBuilder.Add(property);

                    // Property related symbols
                    membersBuilder.Add(property);
                    membersBuilder.Add(property.BackingField);
                    membersBuilder.Add(property.GetMethod);
                }

                _typeParameters = typeParametersBuilder.ToImmutableAndFree();
                this.Properties = propertiesBuilder.ToImmutableAndFree();

                // Add a constructor
                membersBuilder.Add(new AnonymousTypeConstructorSymbol(this, this.Properties));
                _members = membersBuilder.ToImmutableAndFree();
                Debug.Assert(membersCount == _members.Length);

                // fill nameToSymbols map
                foreach (var symbol in _members)
                {
                    _nameToSymbols.Add(symbol.Name, symbol);
                }

                // special members: Equals, GetHashCode, ToString
                this.SpecialMembers = ImmutableArray.Create <MethodSymbol>(
                    new AnonymousTypeEqualsMethodSymbol(this),
                    new AnonymousTypeGetHashCodeMethodSymbol(this),
                    new AnonymousTypeToStringMethodSymbol(this));
            }
Exemplo n.º 17
0
        /// <summary>
        /// If the extension method is applicable based on the "this" argument type, return
        /// the method constructed with the inferred type arguments. If the method is not an
        /// unconstructed generic method, type inference is skipped. If the method is not
        /// applicable, or if constraints when inferring type parameters from the "this" type
        /// are not satisfied, the return value is null.
        /// </summary>
        private static MethodSymbol InferExtensionMethodTypeArguments(MethodSymbol method, TypeSymbol thisType, ref HashSet <DiagnosticInfo> useSiteDiagnostics)
        {
            Debug.Assert(method.IsExtensionMethod);
            Debug.Assert((object)thisType != null);

            if (!method.IsGenericMethod || method != method.ConstructedFrom)
            {
                return(method);
            }

            // We never resolve extension methods on a dynamic receiver.
            if (thisType.IsDynamic())
            {
                return(null);
            }

            var containingAssembly = method.ContainingAssembly;
            var errorNamespace     = containingAssembly.GlobalNamespace;
            var conversions        = new TypeConversions(containingAssembly.CorLibrary);

            // There is absolutely no plausible syntax/tree that we could use for these
            // synthesized literals.  We could be speculatively binding a call to a PE method.
            var syntaxTree = CSharpSyntaxTree.Dummy;
            var syntax     = (CSharpSyntaxNode)syntaxTree.GetRoot();

            // Create an argument value for the "this" argument of specific type,
            // and pass the same bad argument value for all other arguments.
            var thisArgumentValue = new BoundLiteral(syntax, ConstantValue.Bad, thisType)
            {
                WasCompilerGenerated = true
            };
            var otherArgumentType  = new ExtendedErrorTypeSymbol(errorNamespace, name: string.Empty, arity: 0, errorInfo: null, unreported: false);
            var otherArgumentValue = new BoundLiteral(syntax, ConstantValue.Bad, otherArgumentType)
            {
                WasCompilerGenerated = true
            };

            var paramCount = method.ParameterCount;
            var arguments  = new BoundExpression[paramCount];

            for (int i = 0; i < paramCount; i++)
            {
                var argument = (i == 0) ? thisArgumentValue : otherArgumentValue;
                arguments[i] = argument;
            }

            var typeArgs = MethodTypeInferrer.InferTypeArgumentsFromFirstArgument(
                conversions,
                method,
                arguments.AsImmutable(),
                useSiteDiagnostics: ref useSiteDiagnostics);

            if (typeArgs.IsDefault)
            {
                return(null);
            }

            // For the purpose of construction we use original type parameters in place of type arguments that we couldn't infer from the first argument.
            ImmutableArray <TypeWithAnnotations> typeArgsForConstruct = typeArgs;

            if (typeArgs.Any(t => !t.HasType))
            {
                typeArgsForConstruct = typeArgs.ZipAsArray(
                    method.TypeParameters,
                    (t, tp) => t.HasType ? t : TypeWithAnnotations.Create(tp));
            }

            return(method.Construct(typeArgsForConstruct));
        }
Exemplo n.º 18
0
 internal static ImmutableArray <TypeWithAnnotations> TypeParametersAsTypeSymbolsWithAnnotations(ImmutableArray <TypeParameterSymbol> typeParameters)
 {
     return(typeParameters.SelectAsArray((tp) => TypeWithAnnotations.Create(tp)));
 }
Exemplo n.º 19
0
        private ImmutableArray <ParameterSymbol> MakeParameters(
            CSharpCompilation compilation,
            UnboundLambda unboundLambda,
            ImmutableArray <TypeWithAnnotations> parameterTypes,
            ImmutableArray <RefKind> parameterRefKinds,
            DiagnosticBag diagnostics)
        {
            Debug.Assert(parameterTypes.Length == parameterRefKinds.Length);

            if (!unboundLambda.HasSignature || unboundLambda.ParameterCount == 0)
            {
                // The parameters may be omitted in source, but they are still present on the symbol.
                return(parameterTypes.SelectAsArray((type, ordinal, arg) =>
                                                    SynthesizedParameterSymbol.Create(
                                                        arg.owner,
                                                        type,
                                                        ordinal,
                                                        arg.refKinds[ordinal],
                                                        GeneratedNames.LambdaCopyParameterName(ordinal)),     // Make sure nothing binds to this.
                                                    (owner: this, refKinds: parameterRefKinds)));
            }

            var builder = ArrayBuilder <ParameterSymbol> .GetInstance(unboundLambda.ParameterCount);

            var hasExplicitlyTypedParameterList = unboundLambda.HasExplicitlyTypedParameterList;
            var numDelegateParameters           = parameterTypes.Length;

            for (int p = 0; p < unboundLambda.ParameterCount; ++p)
            {
                // If there are no types given in the lambda then used the delegate type.
                // If the lambda is typed then the types probably match the delegate types;
                // if they do not, use the lambda types for binding. Either way, if we
                // can, then we use the lambda types. (Whatever you do, do not use the names
                // in the delegate parameters; they are not in scope!)

                TypeWithAnnotations type;
                RefKind             refKind;
                if (hasExplicitlyTypedParameterList)
                {
                    type    = unboundLambda.ParameterTypeWithAnnotations(p);
                    refKind = unboundLambda.RefKind(p);
                }
                else if (p < numDelegateParameters)
                {
                    type    = parameterTypes[p];
                    refKind = parameterRefKinds[p];
                }
                else
                {
                    type    = TypeWithAnnotations.Create(new ExtendedErrorTypeSymbol(compilation, name: string.Empty, arity: 0, errorInfo: null));
                    refKind = RefKind.None;
                }

                var name      = unboundLambda.ParameterName(p);
                var location  = unboundLambda.ParameterLocation(p);
                var locations = location == null ? ImmutableArray <Location> .Empty : ImmutableArray.Create <Location>(location);

                var parameter = new SourceSimpleParameterSymbol(owner: this, type, ordinal: p, refKind, name, unboundLambda.ParameterIsDiscard(p), locations);

                builder.Add(parameter);
            }

            var result = builder.ToImmutableAndFree();

            return(result);
        }
Exemplo n.º 20
0
            protected override TypeWithAnnotations InferTypeOfVarVariable(BindingDiagnosticBag diagnostics)
            {
                switch (_nodeToBind.Kind())
                {
                case SyntaxKind.ThisConstructorInitializer:
                case SyntaxKind.BaseConstructorInitializer:
                    var initializer = (ConstructorInitializerSyntax)_nodeToBind;
                    _nodeBinder.BindConstructorInitializer(initializer, diagnostics);
                    break;

                case SyntaxKind.PrimaryConstructorBaseType:
                    _nodeBinder.BindConstructorInitializer((PrimaryConstructorBaseTypeSyntax)_nodeToBind, diagnostics);
                    break;

                case SyntaxKind.ArgumentList:
                    switch (_nodeToBind.Parent)
                    {
                    case ConstructorInitializerSyntax ctorInitializer:
                        _nodeBinder.BindConstructorInitializer(ctorInitializer, diagnostics);
                        break;

                    case PrimaryConstructorBaseTypeSyntax ctorInitializer:
                        _nodeBinder.BindConstructorInitializer(ctorInitializer, diagnostics);
                        break;

                    default:
                        throw ExceptionUtilities.UnexpectedValue(_nodeToBind.Parent);
                    }
                    break;

                case SyntaxKind.CasePatternSwitchLabel:
                    _nodeBinder.BindPatternSwitchLabelForInference((CasePatternSwitchLabelSyntax)_nodeToBind, diagnostics);
                    break;

                case SyntaxKind.VariableDeclarator:
                    // This occurs, for example, in
                    // int x, y[out var Z, 1 is int I];
                    // for (int x, y[out var Z, 1 is int I]; ;) {}
                    _nodeBinder.BindDeclaratorArguments((VariableDeclaratorSyntax)_nodeToBind, diagnostics);
                    break;

                case SyntaxKind.SwitchExpressionArm:
                    var arm       = (SwitchExpressionArmSyntax)_nodeToBind;
                    var armBinder = (SwitchExpressionArmBinder)_nodeBinder;
                    armBinder.BindSwitchExpressionArm(arm, diagnostics);
                    break;

                case SyntaxKind.GotoCaseStatement:
                    _nodeBinder.BindStatement((GotoStatementSyntax)_nodeToBind, diagnostics);
                    break;

                default:
                    _nodeBinder.BindExpression((ExpressionSyntax)_nodeToBind, diagnostics);
                    break;
                }

                if (this._type == null)
                {
                    Debug.Assert(this.DeclarationKind == LocalDeclarationKind.DeclarationExpressionVariable);
                    SetTypeWithAnnotations(TypeWithAnnotations.Create(_nodeBinder.CreateErrorType("var")));
                }

                return(_type.Value);
            }
        protected sealed override void MethodChecks(DiagnosticBag diagnostics)
        {
            Debug.Assert(_lazyParameters.IsDefault != _lazyReturnType.HasType);

            // CONSIDER: currently, we're copying the custom modifiers of the event overridden
            // by this method's associated event (by using the associated event's type, which is
            // copied from the overridden event).  It would be more correct to copy them from
            // the specific accessor that this method is overriding (as in SourceMemberMethodSymbol).

            if (_lazyReturnType.IsDefault)
            {
                CSharpCompilation compilation = this.DeclaringCompilation;
                Debug.Assert(compilation != null);

                // NOTE: LazyMethodChecks calls us within a lock, so we use regular assignments,
                // rather than Interlocked.CompareExchange.
                if (_event.IsWindowsRuntimeEvent)
                {
                    TypeSymbol eventTokenType = compilation.GetWellKnownType(WellKnownType.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationToken);
                    Binder.ReportUseSiteDiagnostics(eventTokenType, diagnostics, this.Location);

                    if (this.MethodKind == MethodKind.EventAdd)
                    {
                        // EventRegistrationToken add_E(EventDelegate d);

                        // Leave the returns void bit in this.flags false.
                        _lazyReturnType = TypeWithAnnotations.Create(eventTokenType);

                        var parameter = new SynthesizedAccessorValueParameterSymbol(this, _event.TypeWithAnnotations, 0);
                        _lazyParameters = ImmutableArray.Create <ParameterSymbol>(parameter);
                    }
                    else
                    {
                        Debug.Assert(this.MethodKind == MethodKind.EventRemove);

                        // void remove_E(EventRegistrationToken t);

                        TypeSymbol voidType = compilation.GetSpecialType(SpecialType.System_Void);
                        Binder.ReportUseSiteDiagnostics(voidType, diagnostics, this.Location);
                        _lazyReturnType = TypeWithAnnotations.Create(voidType);
                        this.SetReturnsVoid(returnsVoid: true);

                        var parameter = new SynthesizedAccessorValueParameterSymbol(this, TypeWithAnnotations.Create(eventTokenType), 0);
                        _lazyParameters = ImmutableArray.Create <ParameterSymbol>(parameter);
                    }
                }
                else
                {
                    // void add_E(EventDelegate d);
                    // void remove_E(EventDelegate d);

                    TypeSymbol voidType = compilation.GetSpecialType(SpecialType.System_Void);
                    Binder.ReportUseSiteDiagnostics(voidType, diagnostics, this.Location);
                    _lazyReturnType = TypeWithAnnotations.Create(voidType);
                    this.SetReturnsVoid(returnsVoid: true);

                    var parameter = new SynthesizedAccessorValueParameterSymbol(this, _event.TypeWithAnnotations, 0);
                    _lazyParameters = ImmutableArray.Create <ParameterSymbol>(parameter);
                }
            }
        }
Exemplo n.º 22
0
 protected override TypeWithAnnotations ComputeType(Binder?binder, SyntaxNode syntax, DiagnosticBag diagnostics)
 {
     // No need to worry about reporting use-site diagnostics, we already did that in the constructor
     return(TypeWithAnnotations.Create(DeclaringCompilation.GetWellKnownType(WellKnownType.System_Type), NullableAnnotation.NotAnnotated));
 }
Exemplo n.º 23
0
        protected sealed override void MethodChecks(BindingDiagnosticBag diagnostics)
        {
            var syntax        = (CSharpSyntaxNode)syntaxReferenceOpt.GetSyntax();
            var binderFactory = this.DeclaringCompilation.GetBinderFactory(syntax.SyntaxTree);
            ParameterListSyntax parameterList = GetParameterList();

            // NOTE: if we asked for the binder for the body of the constructor, we'd risk a stack overflow because
            // we might still be constructing the member list of the containing type.  However, getting the binder
            // for the parameters should be safe.
            var bodyBinder = binderFactory
                             .GetBinder(parameterList, syntax, this)
                             .WithContainingMemberOrLambda(this);

            // Constraint checking for parameter and return types must be delayed until
            // the method has been added to the containing type member list since
            // evaluating the constraints may depend on accessing this method from
            // the container (comparing this method to others to find overrides for
            // instance). Constraints are checked in AfterAddingTypeMembersChecks.
            var signatureBinder = bodyBinder.WithAdditionalFlagsAndContainingMemberOrLambda(
                BinderFlags.SuppressConstraintChecks,
                this
                );

            SyntaxToken arglistToken;

            _lazyParameters = ParameterHelpers.MakeParameters(
                signatureBinder,
                this,
                parameterList,
                out arglistToken,
                allowRefOrOut: AllowRefOrOut,
                allowThis: false,
                addRefReadOnlyModifier: false,
                diagnostics: diagnostics
                );

            _lazyIsVararg   = (arglistToken.Kind() == SyntaxKind.ArgListKeyword);
            _lazyReturnType = TypeWithAnnotations.Create(
                bodyBinder.GetSpecialType(SpecialType.System_Void, diagnostics, syntax)
                );

            var location = this.Locations[0];

            // Don't report ERR_StaticConstParam if the ctor symbol name doesn't match the containing type name.
            // This avoids extra unnecessary errors.
            // There will already be a diagnostic saying Method must have a return type.
            if (
                MethodKind == MethodKind.StaticConstructor &&
                (_lazyParameters.Length != 0) &&
                ContainingType.Name
                == ((ConstructorDeclarationSyntax)this.SyntaxNode).Identifier.ValueText
                )
            {
                diagnostics.Add(ErrorCode.ERR_StaticConstParam, location, this);
            }

            this.CheckEffectiveAccessibility(_lazyReturnType, _lazyParameters, diagnostics);

            if (
                _lazyIsVararg &&
                (
                    IsGenericMethod ||
                    ContainingType.IsGenericType ||
                    _lazyParameters.Length > 0 &&
                    _lazyParameters[_lazyParameters.Length - 1].IsParams
                )
                )
            {
                diagnostics.Add(ErrorCode.ERR_BadVarargs, location);
            }
        }