private static void BuildName(NameSyntax nameSyntax, StringBuilder builder, bool includeAlias)
{
if (nameSyntax.IsKind(SyntaxKind.IdentifierName))
{
var identifierNameSyntax = (IdentifierNameSyntax)nameSyntax;
builder.Append(identifierNameSyntax.Identifier.ValueText);
}
else if (nameSyntax.IsKind(SyntaxKind.QualifiedName))
{
var qualifiedNameSyntax = (QualifiedNameSyntax)nameSyntax;
BuildName(qualifiedNameSyntax.Left, builder, includeAlias);
builder.Append(DotChar);
BuildName(qualifiedNameSyntax.Right, builder, includeAlias);
}
else if (nameSyntax.IsKind(SyntaxKind.GenericName))
{
var genericNameSyntax = (GenericNameSyntax)nameSyntax;
builder.AppendFormat("{0}{1}", genericNameSyntax.Identifier.ValueText, genericNameSyntax.TypeArgumentList.ToString());
}
else if (nameSyntax.IsKind(SyntaxKind.AliasQualifiedName))
{
var aliasQualifiedNameSyntax = (AliasQualifiedNameSyntax)nameSyntax;
if (includeAlias)
{
builder.Append(aliasQualifiedNameSyntax.Alias.Identifier.ValueText);
builder.Append("::");
}
builder.Append(aliasQualifiedNameSyntax.Name.Identifier.ValueText);
}
}
private static void AppendName(StringBuilder builder, NameSyntax name)
{
if (name.Kind() == SyntaxKind.QualifiedName)
{
AppendName(builder, ((QualifiedNameSyntax)name).Left);
}
switch (name.Kind())
{
case SyntaxKind.IdentifierName:
AppendDotIfNeeded(builder);
builder.Append(((IdentifierNameSyntax)name).Identifier.ValueText);
break;
case SyntaxKind.GenericName:
var genericName = (GenericNameSyntax)name;
AppendDotIfNeeded(builder);
builder.Append(genericName.Identifier.ValueText);
AppendArity(builder, genericName.Arity);
break;
case SyntaxKind.AliasQualifiedName:
var aliasQualifiedName = (AliasQualifiedNameSyntax)name;
AppendName(builder, aliasQualifiedName.Alias);
builder.Append("::");
AppendName(builder, aliasQualifiedName.Name);
break;
case SyntaxKind.QualifiedName:
AppendName(builder, ((QualifiedNameSyntax)name).Right);
break;
}
}
private async Task<IEnumerable<CompletionItem>> GetCompletionsOffOfExplicitInterfaceAsync(
Document document, SemanticModel semanticModel, int position, NameSyntax name, CancellationToken cancellationToken)
{
// Bind the interface name which is to the left of the dot
var syntaxTree = semanticModel.SyntaxTree;
var nameBinding = semanticModel.GetSymbolInfo(name, cancellationToken);
var context = CSharpSyntaxContext.CreateContext(document.Project.Solution.Workspace, semanticModel, position, cancellationToken);
var symbol = nameBinding.Symbol as ITypeSymbol;
if (symbol == null || symbol.TypeKind != TypeKind.Interface)
{
return SpecializedCollections.EmptyEnumerable<CompletionItem>();
}
var members = semanticModel.LookupSymbols(
position: name.SpanStart,
container: symbol)
.Where(s => !s.IsStatic)
.FilterToVisibleAndBrowsableSymbols(document.ShouldHideAdvancedMembers(), semanticModel.Compilation);
// We're going to create a entry for each one, including the signature
var completions = new List<CompletionItem>();
var signatureDisplayFormat =
new SymbolDisplayFormat(
genericsOptions: SymbolDisplayGenericsOptions.IncludeTypeParameters,
memberOptions:
SymbolDisplayMemberOptions.IncludeParameters,
parameterOptions:
SymbolDisplayParameterOptions.IncludeName |
SymbolDisplayParameterOptions.IncludeType |
SymbolDisplayParameterOptions.IncludeParamsRefOut,
miscellaneousOptions:
SymbolDisplayMiscellaneousOptions.EscapeKeywordIdentifiers |
SymbolDisplayMiscellaneousOptions.UseSpecialTypes);
var namePosition = name.SpanStart;
var text = await context.SyntaxTree.GetTextAsync(cancellationToken).ConfigureAwait(false);
var textChangeSpan = CompletionUtilities.GetTextChangeSpan(text, context.Position);
foreach (var member in members)
{
var displayString = member.ToMinimalDisplayString(semanticModel, namePosition, signatureDisplayFormat);
var memberCopied = member;
var insertionText = displayString;
completions.Add(new SymbolCompletionItem(
this,
displayString,
insertionText: insertionText,
filterSpan: textChangeSpan,
position: position,
symbols: new List<ISymbol> { member },
context: context,
rules: ItemRules.Instance));
}
return completions;
}
private bool TryClassifySymbol(
NameSyntax name,
SymbolInfo symbolInfo,
SemanticModel semanticModel,
CancellationToken cancellationToken,
out IEnumerable<ClassifiedSpan> result)
{
if (symbolInfo.CandidateReason == CandidateReason.Ambiguous)
{
return TryClassifyAmbiguousSymbol(name, symbolInfo, semanticModel, cancellationToken, out result);
}
// Only classify if we get one good symbol back, or if it bound to a constructor symbol with
// overload resolution/accessibility errors, or bound to type/constructor and type wasn't creatable.
var symbol = TryGetSymbol(name, symbolInfo, semanticModel);
ClassifiedSpan classifiedSpan;
if (TryClassifySymbol(name, symbol, semanticModel, cancellationToken, out classifiedSpan))
{
result = SpecializedCollections.SingletonEnumerable(classifiedSpan);
return true;
}
result = null;
return false;
}
private static bool IsNamespaceName(NameSyntax name)
{
while (name.Parent is NameSyntax)
{
name = (NameSyntax)name.Parent;
}
return name.IsParentKind(SyntaxKind.NamespaceDeclaration);
}
public DeltaGen(CodeGen generator)
: base(generator)
{
var recursiveType = this.applyTo.RecursiveTypeFromFamily;
if (!recursiveType.IsDefault)
{
this.changedPropertiesEnumTypeName = SyntaxFactory.IdentifierName(recursiveType.TypeSymbol.Name + "ChangedProperties");
this.diffGramTypeSyntax = SyntaxFactory.QualifiedName(recursiveType.TypeSyntax, DiffGramTypeName);
this.recursiveDiffingType = SyntaxFactory.QualifiedName(
SyntaxFactory.IdentifierName(nameof(ImmutableObjectGraph)),
SyntaxFactory.GenericName(nameof(ImmutableObjectGraph.IRecursiveDiffingType<uint, uint>))
.AddTypeArgumentListArguments(
this.changedPropertiesEnumTypeName,
this.diffGramTypeSyntax));
}
}
private Document IntroduceQueryLocalForSingleOccurrence(
SemanticDocument document,
ExpressionSyntax expression,
NameSyntax newLocalName,
LetClauseSyntax letClause,
bool allOccurrences,
CancellationToken cancellationToken)
{
var oldClause = expression.GetAncestors<SyntaxNode>().First(IsAnyQueryClause);
var newClause = Rewrite(
document, expression, newLocalName, document, oldClause, allOccurrences, cancellationToken);
var oldQuery = (QueryBodySyntax)oldClause.Parent;
var newQuery = GetNewQuery(oldQuery, oldClause, newClause, letClause);
var newRoot = document.Root.ReplaceNode(oldQuery, newQuery);
return document.Document.WithSyntaxRoot(newRoot);
}
private static ISymbol TryGetSymbol(NameSyntax name, SymbolInfo symbolInfo, SemanticModel semanticModel)
{
if (symbolInfo.Symbol == null && symbolInfo.CandidateSymbols.Length > 0)
{
var firstSymbol = symbolInfo.CandidateSymbols[0];
switch (symbolInfo.CandidateReason)
{
case CandidateReason.NotAValue:
return firstSymbol;
case CandidateReason.NotCreatable:
// We want to color types even if they can't be constructed.
if (firstSymbol.IsConstructor() || firstSymbol is ITypeSymbol)
{
return firstSymbol;
}
break;
case CandidateReason.OverloadResolutionFailure:
// If we couldn't bind to a constructor, still classify the type.
if (firstSymbol.IsConstructor())
{
return firstSymbol;
}
break;
case CandidateReason.Inaccessible:
// If a constructor wasn't accessible, still classify the type if it's accessible.
if (firstSymbol.IsConstructor() && semanticModel.IsAccessible(name.SpanStart, firstSymbol.ContainingType))
{
return firstSymbol;
}
break;
}
}
return symbolInfo.Symbol;
}
private IEnumerable<ClassifiedSpan> ClassifyTypeSyntax(
NameSyntax name,
SemanticModel semanticModel,
CancellationToken cancellationToken)
{
if (!IsNamespaceName(name))
{
var symbolInfo = semanticModel.GetSymbolInfo(name, cancellationToken);
IEnumerable<ClassifiedSpan> result;
if (TryClassifySymbol(name, symbolInfo, semanticModel, cancellationToken, out result) ||
TryClassifyFromIdentifier(name, symbolInfo, out result) ||
TryClassifyValueIdentifier(name, symbolInfo, out result))
{
return result;
}
}
return null;
}
public FastSpineGen(CodeGen generator)
: base(generator)
{
if (this.applyTo.IsRecursive || this.applyTo.IsRecursiveParentOrDerivative)
{
var keyValuePairType = SyntaxFactory.ParseTypeName(
string.Format(
CultureInfo.InvariantCulture,
"System.Collections.Generic.KeyValuePair<{1}, {0}>",
IdentityFieldTypeSyntax,
this.applyTo.RecursiveTypeFromFamily.TypeSyntax));
this.lookupTableType = SyntaxFactory.ParseTypeName(
string.Format(
CultureInfo.InvariantCulture,
"System.Collections.Immutable.ImmutableDictionary<{0}, {1}>",
IdentityFieldTypeSyntax,
keyValuePairType));
this.IRecursiveParentWithChildReplacementType = SyntaxFactory.QualifiedName(
SyntaxFactory.IdentifierName(nameof(ImmutableObjectGraph)),
SyntaxFactory.GenericName(nameof(IRecursiveParentWithChildReplacement<IRecursiveType>))
.AddTypeArgumentListArguments(this.applyTo.RecursiveType.TypeSyntax));
}
}
private static void CheckNameSyntax(SyntaxNodeAnalysisContext context, NameSyntax nameSyntax)
{
if (nameSyntax == null || nameSyntax.IsMissing)
{
return;
}
QualifiedNameSyntax qualifiedNameSyntax = nameSyntax as QualifiedNameSyntax;
if (qualifiedNameSyntax != null)
{
CheckNameSyntax(context, qualifiedNameSyntax.Left);
CheckNameSyntax(context, qualifiedNameSyntax.Right);
return;
}
SimpleNameSyntax simpleNameSyntax = nameSyntax as SimpleNameSyntax;
if (simpleNameSyntax != null)
{
CheckElementNameToken(context, simpleNameSyntax.Identifier);
return;
}
// TODO: any other cases?
}
private static ImmutableArray<ISymbol> GetSymbolsOffOfName(
CSharpSyntaxContext context,
NameSyntax name,
CancellationToken cancellationToken)
{
// Check if we're in an interesting situation like this:
//
// int i = 5;
// i. // <-- here
// List<string> ml = new List<string>();
// The problem is that "i.List<string>" gets parsed as a type. In this case we need to
// try binding again as if "i" is an expression and not a type. In order to do that, we
// need to speculate as to what 'i' meant if it wasn't part of a local declaration's
// type.
if (name.IsFoundUnder<LocalDeclarationStatementSyntax>(d => d.Declaration.Type))
{
var speculativeBinding = context.SemanticModel.GetSpeculativeSymbolInfo(name.SpanStart, name, SpeculativeBindingOption.BindAsExpression);
var container = context.SemanticModel.GetSpeculativeTypeInfo(name.SpanStart, name, SpeculativeBindingOption.BindAsExpression).Type;
return GetSymbolsOffOfBoundExpression(context, name, name, speculativeBinding, container, cancellationToken);
}
// We're in a name-only context, since if we were an expression we'd be a
// MemberAccessExpressionSyntax. Thus, let's do other namespaces and types.
var nameBinding = context.SemanticModel.GetSymbolInfo(name, cancellationToken);
var symbol = nameBinding.Symbol as INamespaceOrTypeSymbol;
if (symbol != null)
{
if (context.IsNameOfContext)
{
return context.SemanticModel.LookupSymbols(position: name.SpanStart, container: symbol);
}
var symbols = context.SemanticModel.LookupNamespacesAndTypes(
position: name.SpanStart,
container: symbol);
if (context.IsNamespaceDeclarationNameContext)
{
var declarationSyntax = name.GetAncestorOrThis<NamespaceDeclarationSyntax>();
return symbols.WhereAsArray(s => IsNonIntersectingNamespace(s, declarationSyntax));
}
// Filter the types when in a using directive, but not an alias.
//
// Cases:
// using | -- Show namespaces
// using A.| -- Show namespaces
// using static | -- Show namespace and types
// using A = B.| -- Show namespace and types
var usingDirective = name.GetAncestorOrThis<UsingDirectiveSyntax>();
if (usingDirective != null && usingDirective.Alias == null)
{
if (usingDirective.StaticKeyword.IsKind(SyntaxKind.StaticKeyword))
{
return symbols.WhereAsArray(s => !s.IsDelegateType() && !s.IsInterfaceType());
}
else
{
symbols = symbols.WhereAsArray(s => s.IsNamespace());
}
}
if (symbols.Any())
{
return symbols;
}
}
return ImmutableArray<ISymbol>.Empty;
}
private Symbol GetDeclaredMember(NamespaceOrTypeSymbol container, TextSpan declarationSpan, NameSyntax name)
{
switch (name.Kind())
{
case SyntaxKind.GenericName:
case SyntaxKind.IdentifierName:
return GetDeclaredMember(container, declarationSpan, ((SimpleNameSyntax)name).Identifier.ValueText);
case SyntaxKind.QualifiedName:
var qn = (QualifiedNameSyntax)name;
var left = GetDeclaredMember(container, declarationSpan, qn.Left) as NamespaceOrTypeSymbol;
Debug.Assert((object)left != null);
return GetDeclaredMember(left, declarationSpan, qn.Right);
case SyntaxKind.AliasQualifiedName:
// this is not supposed to happen, but we allow for errors don't we!
var an = (AliasQualifiedNameSyntax)name;
return GetDeclaredMember(container, declarationSpan, an.Name);
default:
throw ExceptionUtilities.UnexpectedValue(name.Kind());
}
}
bool IsRewritableMethod(NameSyntax methodNameSyntax)
{
var symbol = model.GetSymbolInfo(methodNameSyntax).Symbol as IMethodSymbol;
return symbol != null && symbol.HasAttribute<MetaRewriteTypeArgsAttribute>(model.Compilation);
}
private static bool PreferPredefinedTypeKeywordInDeclarations(NameSyntax name, OptionSet optionSet, SemanticModel semanticModel)
{
return !IsInMemberAccessContext(name) &&
!InsideCrefReference(name) &&
!InsideNameOfExpression(name, semanticModel) &&
SimplificationHelpers.PreferPredefinedTypeKeywordInDeclarations(optionSet, semanticModel.Language);
}
private static bool IsInScriptClass(SemanticModel model, NameSyntax name)
{
var symbol = model.GetSymbolInfo(name).Symbol as INamedTypeSymbol;
while (symbol != null)
{
if (symbol.IsScriptClass)
{
return true;
}
symbol = symbol.ContainingType;
}
return false;
}
private static bool IsQualifiedNameInUsingDirective(SemanticModel model, NameSyntax name, TypeSyntax reducedName)
{
while (name.IsLeftSideOfQualifiedName())
{
name = (NameSyntax)name.Parent;
}
if (name.IsParentKind(SyntaxKind.UsingDirective) &&
((UsingDirectiveSyntax)name.Parent).Alias == null)
{
// We're a qualified name in a using. We don't want to reduce this name as people like
// fully qualified names in usings so they can properly tell what the name is resolving
// to.
// However, if this name is actually referencing the special Script class, then we do
// want to allow that to be reduced.
return !IsInScriptClass(model, name);
}
return false;
}
private bool TryClassifyFromIdentifier(
NameSyntax name,
SymbolInfo symbolInfo,
out IEnumerable<ClassifiedSpan> result)
{
// Okay - it wasn't a type. If the syntax matches "var q = from" or "q = from", and from
// doesn't bind to anything then optimistically color from as a keyword.
var identifierName = name as IdentifierNameSyntax;
if (identifierName != null &&
identifierName.Identifier.HasMatchingText(SyntaxKind.FromKeyword) &&
symbolInfo.Symbol == null)
{
var token = identifierName.Identifier;
if (identifierName.IsRightSideOfAnyAssignExpression() || identifierName.IsVariableDeclaratorValue())
{
result = SpecializedCollections.SingletonEnumerable(
new ClassifiedSpan(token.Span, ClassificationTypeNames.Keyword));
return true;
}
}
result = null;
return false;
}
private static bool PreferPredefinedTypeKeywordInDeclarations(NameSyntax name, OptionSet optionSet, SemanticModel semanticModel)
{
return (name.Parent != null) && !(name.Parent is MemberAccessExpressionSyntax) &&
!InsideCrefReference(name) && !InsideNameOfExpression(name, semanticModel) &&
optionSet.GetOption(SimplificationOptions.PreferIntrinsicPredefinedTypeKeywordInDeclaration, LanguageNames.CSharp);
}
private bool TryClassifySymbol(
NameSyntax name,
ISymbol symbol,
SemanticModel semanticModel,
CancellationToken cancellationToken,
out ClassifiedSpan classifiedSpan)
{
if (symbol != null)
{
// see through using aliases
if (symbol.Kind == SymbolKind.Alias)
{
symbol = (symbol as IAliasSymbol).Target;
}
else if (symbol.IsConstructor() && name.IsParentKind(SyntaxKind.Attribute))
{
symbol = symbol.ContainingType;
}
}
if (name.IsVar &&
IsInVarContext(name))
{
var alias = semanticModel.GetAliasInfo(name, cancellationToken);
if (alias == null || alias.Name != "var")
{
if (!IsSymbolCalledVar(symbol))
{
// We bound to a symbol. If we bound to a symbol called "var" then we want to
// classify this appropriately as a type. Otherwise, we want to classify this as
// a keyword.
classifiedSpan = new ClassifiedSpan(name.Span, ClassificationTypeNames.Keyword);
return true;
}
}
}
if (symbol != null)
{
// Use .Equals since we can't rely on object identity for constructed types.
if (symbol is ITypeSymbol)
{
var classification = GetClassificationForType((ITypeSymbol)symbol);
if (classification != null)
{
var token = name.GetNameToken();
classifiedSpan = new ClassifiedSpan(token.Span, classification);
return true;
}
}
}
classifiedSpan = default(ClassifiedSpan);
return false;
}
private static bool TryReduceAttributeSuffix(
NameSyntax name,
SyntaxToken identifierToken,
SemanticModel semanticModel,
out TypeSyntax replacementNode,
out TextSpan issueSpan,
CancellationToken cancellationToken)
{
issueSpan = default(TextSpan);
replacementNode = default(TypeSyntax);
// we can try to remove the Attribute suffix if this is the attribute name
if (SyntaxFacts.IsAttributeName(name))
{
if (name.Parent.Kind() == SyntaxKind.Attribute || name.IsRightSideOfDotOrColonColon())
{
const string AttributeName = "Attribute";
// an attribute that should keep it (unnecessary "Attribute" suffix should be annotated with a DontSimplifyAnnotation
if (identifierToken.ValueText != AttributeName && identifierToken.ValueText.EndsWith(AttributeName, StringComparison.Ordinal) && !identifierToken.HasAnnotation(SimplificationHelpers.DontSimplifyAnnotation))
{
// weird. the semantic model is able to bind attribute syntax like "[as()]" although it's not valid code.
// so we need another check for keywords manually.
var newAttributeName = identifierToken.ValueText.Substring(0, identifierToken.ValueText.Length - 9);
if (SyntaxFacts.GetKeywordKind(newAttributeName) != SyntaxKind.None)
{
return false;
}
// if this attribute name in source contained unicode escaping, we will loose it now
// because there is no easy way to determine the substring from identifier->ToString()
// which would be needed to pass to SyntaxFactory.Identifier
// The result is an unescaped unicode character in source.
// once we remove the Attribute suffix, we can't use an escaped identifier
var newIdentifierToken = identifierToken.CopyAnnotationsTo(
SyntaxFactory.Identifier(
identifierToken.LeadingTrivia,
newAttributeName,
identifierToken.TrailingTrivia));
replacementNode = SyntaxFactory.IdentifierName(newIdentifierToken)
.WithLeadingTrivia(name.GetLeadingTrivia());
issueSpan = new TextSpan(identifierToken.Span.End - 9, 9);
return true;
}
}
}
return false;
}
private bool TryClassifyNameOfIdentifier(NameSyntax name, SymbolInfo symbolInfo, out IEnumerable<ClassifiedSpan> result)
{
var identifierName = name as IdentifierNameSyntax;
if (identifierName != null &&
identifierName.Identifier.IsKindOrHasMatchingText(SyntaxKind.NameOfKeyword) &&
symbolInfo.Symbol == null &&
!symbolInfo.CandidateSymbols.Any())
{
result = SpecializedCollections.SingletonEnumerable(new ClassifiedSpan(identifierName.Identifier.Span, ClassificationTypeNames.Keyword));
return true;
}
result = null;
return false;
}
private bool TryClassifyValueIdentifier(
NameSyntax name,
SymbolInfo symbolInfo,
out IEnumerable<ClassifiedSpan> result)
{
var identifierName = name as IdentifierNameSyntax;
if (symbolInfo.Symbol.IsImplicitValueParameter())
{
result = SpecializedCollections.SingletonEnumerable(
new ClassifiedSpan(identifierName.Identifier.Span, ClassificationTypeNames.Keyword));
return true;
}
result = null;
return false;
}
private static bool CanSimplifyNullable(INamedTypeSymbol type, NameSyntax name, SemanticModel semanticModel)
{
if (!type.IsNullable())
{
return false;
}
if (type.IsUnboundGenericType)
{
// Don't simplify unbound generic type "Nullable<>".
return false;
}
if (InsideNameOfExpression(name, semanticModel))
{
// Nullable<T> can't be simplified to T? in nameof expressions.
return false;
}
if (!InsideCrefReference(name))
{
// Nullable<T> can always be simplified to T? outside crefs.
return true;
}
// Inside crefs, if the T in this Nullable{T} is being declared right here
// then this Nullable{T} is not a constructed generic type and we should
// not offer to simplify this to T?.
//
// For example, we should not offer the simplification in the following cases where
// T does not bind to an existing type / type parameter in the user's code.
// - <see cref="Nullable{T}"/>
// - <see cref="System.Nullable{T}.Value"/>
//
// And we should offer the simplification in the following cases where SomeType and
// SomeMethod bind to a type and method declared elsewhere in the users code.
// - <see cref="SomeType.SomeMethod(Nullable{SomeType})"/>
var argument = type.TypeArguments.SingleOrDefault();
if (argument == null || argument.IsErrorType())
{
return false;
}
var argumentDecl = argument.DeclaringSyntaxReferences.FirstOrDefault();
if (argumentDecl == null)
{
// The type argument is a type from metadata - so this is a constructed generic nullable type that can be simplified (e.g. Nullable(Of Integer)).
return true;
}
return !name.Span.Contains(argumentDecl.Span);
}
private static bool CanReplaceWithPredefinedTypeKeywordInContext(
NameSyntax name,
SemanticModel semanticModel,
out TypeSyntax replacementNode,
ref TextSpan issueSpan,
SyntaxKind keywordKind,
string codeStyleOptionName,
CancellationToken cancellationToken)
{
replacementNode = CreatePredefinedTypeSyntax(name, keywordKind);
issueSpan = name.Span; // we want to show the whole name expression as unnecessary
var canReduce = name.CanReplaceWithReducedNameInContext(replacementNode, semanticModel, cancellationToken);
if (canReduce)
{
replacementNode = replacementNode.WithAdditionalAnnotations(new SyntaxAnnotation(codeStyleOptionName));
}
return canReduce;
}
private static bool CanReplaceWithPredefinedTypeKeywordInContext(NameSyntax name, SemanticModel semanticModel, out TypeSyntax replacementNode, ref TextSpan issueSpan, SyntaxKind keywordKind, CancellationToken cancellationToken)
{
replacementNode = CreatePredefinedTypeSyntax(name, keywordKind);
issueSpan = name.Span; // we want to show the whole name expression as unnecessary
return name.CanReplaceWithReducedNameInContext(replacementNode, semanticModel, cancellationToken);
}
private bool IsInVarContext(NameSyntax name)
{
return
name.CheckParent<VariableDeclarationSyntax>(v => v.Type == name) ||
name.CheckParent<ForEachStatementSyntax>(f => f.Type == name) ||
name.CheckParent<TypedVariableComponentSyntax>(f => f.Type == name);
}
private static bool ContainsOpenName(NameSyntax name)
{
if (name is QualifiedNameSyntax)
{
var qualifiedName = (QualifiedNameSyntax)name;
return ContainsOpenName(qualifiedName.Left) || ContainsOpenName(qualifiedName.Right);
}
else if (name is GenericNameSyntax)
{
return ((GenericNameSyntax)name).IsUnboundGenericName;
}
else
{
return false;
}
}
private bool TryClassifyAmbiguousSymbol(
NameSyntax name,
SymbolInfo symbolInfo,
SemanticModel semanticModel,
CancellationToken cancellationToken,
out IEnumerable<ClassifiedSpan> result)
{
// If everything classifies the same way, then just pick that classification.
var set = new HashSet<ClassifiedSpan>();
foreach (var symbol in symbolInfo.CandidateSymbols)
{
ClassifiedSpan classifiedSpan;
if (TryClassifySymbol(name, symbol, semanticModel, cancellationToken, out classifiedSpan))
{
set.Add(classifiedSpan);
}
}
if (set.Count == 1)
{
result = SpecializedCollections.SingletonEnumerable(set.First());
return true;
}
result = null;
return false;
}
private bool CompareNames(NameSyntax oldName, NameSyntax newName)
{
if (oldName.Kind() != newName.Kind())
{
return false;
}
switch (oldName.Kind())
{
case SyntaxKind.IdentifierName:
var oldIdentifierName = (IdentifierNameSyntax)oldName;
var newIdentifierName = (IdentifierNameSyntax)newName;
return StringComparer.Ordinal.Equals(oldIdentifierName.Identifier.ToString(), newIdentifierName.Identifier.ToString());
case SyntaxKind.QualifiedName:
var oldQualifiedName = (QualifiedNameSyntax)oldName;
var newQualifiedName = (QualifiedNameSyntax)newName;
return CompareNames(oldQualifiedName.Left, newQualifiedName.Left)
&& CompareNames(oldQualifiedName.Right, oldQualifiedName.Right);
case SyntaxKind.GenericName:
var oldGenericName = (GenericNameSyntax)oldName;
var newGenericName = (GenericNameSyntax)newName;
if (!StringComparer.Ordinal.Equals(oldGenericName.Identifier.ToString(), newGenericName.Identifier.ToString()))
{
return false;
}
if (oldGenericName.Arity != newGenericName.Arity)
{
return false;
}
for (int i = 0; i < oldGenericName.Arity; i++)
{
if (!CompareTypes(oldGenericName.TypeArgumentList.Arguments[i], newGenericName.TypeArgumentList.Arguments[i]))
{
return false;
}
}
return true;
case SyntaxKind.AliasQualifiedName:
var oldAliasQualifiedName = (AliasQualifiedNameSyntax)oldName;
var newAliasQualifiedName = (AliasQualifiedNameSyntax)newName;
return CompareNames(oldAliasQualifiedName.Alias, newAliasQualifiedName.Alias)
&& CompareNames(oldAliasQualifiedName.Name, newAliasQualifiedName.Name);
}
Debug.Fail("Unknown kind: " + oldName.Kind());
return false;
}
public NamespaceDeclarationSyntax Update(SyntaxToken namespaceKeyword, NameSyntax name, SyntaxToken openBraceToken, SyntaxList <ExternAliasDirectiveSyntax> externs, SyntaxList <UsingDirectiveSyntax> usings, SyntaxList <MemberDeclarationSyntax> members, SyntaxToken closeBraceToken, SyntaxToken semicolonToken) => this.Update(this.AttributeLists, this.Modifiers, namespaceKeyword, name, openBraceToken, externs, usings, members, closeBraceToken, semicolonToken);
