private BoundExpression RewriteStringConcatenationThreeExprs(SyntaxNode syntax, BoundExpression loweredFirst, BoundExpression loweredSecond, BoundExpression loweredThird)
{
SpecialMember member = (loweredFirst.Type.SpecialType == SpecialType.System_String &&
loweredSecond.Type.SpecialType == SpecialType.System_String &&
loweredThird.Type.SpecialType == SpecialType.System_String) ?
SpecialMember.System_String__ConcatStringStringString :
SpecialMember.System_String__ConcatObjectObjectObject;
var method = UnsafeGetSpecialTypeMethod(syntax, member);
Debug.Assert((object)method != null);
return(BoundCall.Synthesized(syntax, null, method, ImmutableArray.Create(loweredFirst, loweredSecond, loweredThird)));
}
/// <summary>
/// Strangely enough there is such a thing as unary concatenation and it must be rewritten.
/// </summary>
private BoundExpression RewriteStringConcatenationOneExpr(SyntaxNode syntax, BoundExpression loweredOperand)
{
if (loweredOperand.Type.SpecialType == SpecialType.System_String)
{
// loweredOperand ?? ""
return(_factory.Coalesce(loweredOperand, _factory.Literal("")));
}
var method = UnsafeGetSpecialTypeMethod(syntax, SpecialMember.System_String__ConcatObject);
Debug.Assert((object)method != null);
return((BoundExpression)BoundCall.Synthesized(syntax, null, method, loweredOperand));
}
/// <summary>
/// Checks whether the expression represents a boxing conversion of a special value type.
/// If it does, it tries to return a string-based representation instead in order
/// to avoid allocations. If it can't, the original expression is returned.
/// </summary>
private BoundExpression ConvertConcatExprToStringIfPossible(SyntaxNode syntax, BoundExpression expr)
{
if (expr.Kind == BoundKind.Conversion)
{
BoundConversion conv = (BoundConversion)expr;
if (conv.ConversionKind == ConversionKind.Boxing)
{
BoundExpression operand = conv.Operand;
if (operand != null)
{
// Is the expression a literal char? If so, we can
// simply make it a literal string instead and avoid any
// allocations for converting the char to a string at run time.
if (operand.Kind == BoundKind.Literal)
{
ConstantValue cv = ((BoundLiteral)operand).ConstantValue;
if (cv != null && cv.SpecialType == SpecialType.System_Rune)
{
return(_factory.StringLiteral(cv.RuneValue.ToString()));
}
}
// Can the expression be optimized with a ToString call?
// If so, we can synthesize a ToString call to avoid boxing.
if (ConcatExprCanBeOptimizedWithToString(operand.Type))
{
var toString = UnsafeGetSpecialTypeMethod(syntax, SpecialMember.System_Object__ToString);
var type = (NamedTypeSymbol)operand.Type;
var toStringMembers = type.GetMembers(toString.Name);
foreach (var member in toStringMembers)
{
var toStringMethod = member as MethodSymbol;
if (toStringMethod.GetLeastOverriddenMethod(type) == (object)toString)
{
return(BoundCall.Synthesized(syntax, operand, toStringMethod));
}
}
}
}
}
}
// Optimization not possible; just return the original expression.
return(expr);
}
private BoundExpression VisitCall(BoundCall node)
{
if (node.IsDelegateCall)
{
// Generate Expression.Invoke(Receiver, arguments)
return(ExprFactory(WellKnownMemberNames.DelegateInvokeName, Visit(node.ReceiverOpt), Expressions(node.Arguments)));
}
else
{
// Generate Expression.Call(Receiver, Method, [typeArguments,] arguments)
var method = node.Method;
return(ExprFactory(
"Call",
method.IsStatic ? _bound.Null(ExpressionType) : Visit(node.ReceiverOpt),
_bound.MethodInfo(method),
Expressions(node.Arguments)));
}
}
public override BoundNode VisitCall(BoundCall node)
{
bool mightMutate =
// might be a call to a local function that assigns something
node.Method.MethodKind == MethodKind.LocalFunction ||
// or perhaps we are passing a variable by ref and mutating it that way
!node.ArgumentRefKindsOpt.IsDefault;
if (mightMutate)
{
_mightAssignSomething = true;
}
else
{
base.VisitCall(node);
}
return(null);
}
private BoundExpression RewriteStringConcatenationManyExprs(SyntaxNode syntax, ImmutableArray <BoundExpression> loweredArgs)
{
Debug.Assert(loweredArgs.Length > 3);
Debug.Assert(loweredArgs.All(a => a.HasErrors || a.Type.SpecialType == SpecialType.System_Object || a.Type.SpecialType == SpecialType.System_String));
bool isObject = false;
TypeSymbol elementType = null;
foreach (var arg in loweredArgs)
{
elementType = arg.Type;
if (elementType.SpecialType != SpecialType.System_String)
{
isObject = true;
break;
}
}
// Count == 4 is handled differently because there is a Concat method with 4 arguments
// for strings, but there is no such method for objects.
if (!isObject && loweredArgs.Length == 4)
{
SpecialMember member = SpecialMember.System_String__ConcatStringStringStringString;
var method = UnsafeGetSpecialTypeMethod(syntax, member);
Debug.Assert((object)method != null);
return((BoundExpression)BoundCall.Synthesized(syntax, null, method, loweredArgs));
}
else
{
SpecialMember member = isObject ?
SpecialMember.System_String__ConcatObjectArray :
SpecialMember.System_String__ConcatStringArray;
var method = UnsafeGetSpecialTypeMethod(syntax, member);
Debug.Assert((object)method != null);
var array = _factory.ArrayOrEmpty(elementType, loweredArgs);
return((BoundExpression)BoundCall.Synthesized(syntax, null, method, array));
}
}
private BoundExpression MakePropertyGetAccess(
SyntaxNode syntax,
BoundExpression rewrittenReceiver,
PropertySymbol property,
ImmutableArray <BoundExpression> rewrittenArguments,
MethodSymbol getMethodOpt = null,
BoundPropertyAccess oldNodeOpt = null)
{
var getMethod = getMethodOpt ?? property.GetOwnOrInheritedGetMethod();
Debug.Assert((object)getMethod != null);
Debug.Assert(getMethod.ParameterCount == rewrittenArguments.Length);
Debug.Assert(((object)getMethodOpt == null) || ReferenceEquals(getMethod, getMethodOpt));
return(BoundCall.Synthesized(
syntax,
rewrittenReceiver,
getMethod,
rewrittenArguments));
}
private BoundExpression MakeNewT(SyntaxNode syntax, TypeParameterSymbol typeParameter)
{
// "new T()" is rewritten as: "Activator.CreateInstance<T>()".
// NOTE: DIFFERENCE FROM DEV12
// Dev12 tried to statically optimize this and would emit default(T) if T happens to be struct
// However semantics of "new" in C# requires that parameterless constructor be called
// if struct defines one.
// Since we cannot know if T has a parameterless constructor statically,
// we must call Activator.CreateInstance unconditionally.
MethodSymbol method;
if (!this.TryGetWellKnownTypeMember(syntax, WellKnownMember.System_Activator__CreateInstance_T, out method))
{
return(new BoundDefaultExpression(syntax, null, type: typeParameter, hasErrors: true));
}
Debug.Assert((object)method != null);
method = method.Construct(ImmutableArray.Create <TypeSymbol>(typeParameter));
var createInstanceCall = new BoundCall(
syntax,
null,
method,
ImmutableArray <BoundExpression> .Empty,
default(ImmutableArray <string>),
default(ImmutableArray <RefKind>),
isDelegateCall: false,
expanded: false,
invokedAsExtensionMethod: false,
argsToParamsOpt: default(ImmutableArray <int>),
resultKind: LookupResultKind.Viable,
binderOpt: null,
type: typeParameter);
return(createInstanceCall);
}
private static BoundCall ReverseLastTwoParameterOrder(BoundCall result)
{
// The input call has its arguments in the appropriate order for the invocation, but its last
// two argument expressions appear in the reverse order from which they appeared in source.
// Since we want region analysis to see them in source order, we rewrite the call so that these
// two arguments are evaluated in source order.
int n = result.Arguments.Length;
var arguments = ArrayBuilder <BoundExpression> .GetInstance();
arguments.AddRange(result.Arguments);
var lastArgument = arguments[n - 1];
arguments[n - 1] = arguments[n - 2];
arguments[n - 2] = lastArgument;
var argsToParams = ArrayBuilder <int> .GetInstance();
argsToParams.AddRange(Enumerable.Range(0, n));
argsToParams[n - 1] = n - 2;
argsToParams[n - 2] = n - 1;
return(result.Update(
result.ReceiverOpt, result.Method, arguments.ToImmutableAndFree(), default(ImmutableArray <string>),
default(ImmutableArray <RefKind>), result.IsDelegateCall, result.Expanded, result.InvokedAsExtensionMethod,
argsToParams.ToImmutableAndFree(), result.ResultKind, result.BinderOpt, result.Type));
}
public override BoundNode VisitCall(BoundCall node)
{
VisitCall(node.Method, null, node.Arguments, node.ArgumentRefKindsOpt, node.ArgumentNamesOpt, node.Expanded, node);
CheckReceiverIfField(node.ReceiverOpt);
return(base.VisitCall(node));
}
internal static BoundBlock ConstructDestructorBody(MethodSymbol method, BoundBlock block)
{
var syntax = block.Syntax;
Debug.Assert(method.MethodKind == MethodKind.Destructor);
Debug.Assert(syntax.Kind() == SyntaxKind.Block || syntax.Kind() == SyntaxKind.ArrowExpressionClause);
// If this is a destructor and a base type has a Finalize method (see GetBaseTypeFinalizeMethod for exact
// requirements), then we need to call that method in a finally block. Otherwise, just return block as-is.
// NOTE: the Finalize method need not be a destructor or be overridden by the current method.
MethodSymbol baseTypeFinalize = GetBaseTypeFinalizeMethod(method);
if ((object)baseTypeFinalize != null)
{
BoundStatement baseFinalizeCall = new BoundExpressionStatement(
syntax,
BoundCall.Synthesized(
syntax,
new BoundBaseReference(
syntax,
method.ContainingType)
{
WasCompilerGenerated = true
},
baseTypeFinalize))
{
WasCompilerGenerated = true
};
if (syntax.Kind() == SyntaxKind.Block)
{
//sequence point to mimic Dev10
baseFinalizeCall = new BoundSequencePointWithSpan(
syntax,
baseFinalizeCall,
((BlockSyntax)syntax).CloseBraceToken.Span);
}
return(new BoundBlock(
syntax,
ImmutableArray <LocalSymbol> .Empty,
ImmutableArray.Create <BoundStatement>(
new BoundTryStatement(
syntax,
block,
ImmutableArray <BoundCatchBlock> .Empty,
new BoundBlock(
syntax,
ImmutableArray <LocalSymbol> .Empty,
ImmutableArray.Create <BoundStatement>(
baseFinalizeCall)
)
{
WasCompilerGenerated = true
}
)
{
WasCompilerGenerated = true
})));
}
return(block);
}
/// <summary>
/// Generate a thread-safe accessor for a regular field-like event.
///
/// DelegateType tmp0 = _event; //backing field
/// DelegateType tmp1;
/// DelegateType tmp2;
/// do {
/// tmp1 = tmp0;
/// tmp2 = (DelegateType)Delegate.Combine(tmp1, value); //Remove for -=
/// tmp0 = Interlocked.CompareExchange<DelegateType>(ref _event, tmp2, tmp1);
/// } while ((object)tmp0 != (object)tmp1);
///
/// Note, if System.Threading.Interlocked.CompareExchange<T> is not available,
/// we emit the following code and mark the method Synchronized (unless it is a struct).
///
/// _event = (DelegateType)Delegate.Combine(_event, value); //Remove for -=
///
/// </summary>
internal static BoundBlock ConstructFieldLikeEventAccessorBody_Regular(SourceEventSymbol eventSymbol, bool isAddMethod, CSharpCompilation compilation, DiagnosticBag diagnostics)
{
CSharpSyntaxNode syntax = eventSymbol.CSharpSyntaxNode;
TypeSymbol delegateType = eventSymbol.Type.TypeSymbol;
MethodSymbol accessor = isAddMethod ? eventSymbol.AddMethod : eventSymbol.RemoveMethod;
ParameterSymbol thisParameter = accessor.ThisParameter;
TypeSymbol boolType = compilation.GetSpecialType(SpecialType.System_Boolean);
SpecialMember updateMethodId = isAddMethod ? SpecialMember.System_Delegate__Combine : SpecialMember.System_Delegate__Remove;
MethodSymbol updateMethod = (MethodSymbol)compilation.GetSpecialTypeMember(updateMethodId);
BoundStatement @return = new BoundReturnStatement(syntax,
refKind: RefKind.None,
expressionOpt: null)
{
WasCompilerGenerated = true
};
if (updateMethod == null)
{
MemberDescriptor memberDescriptor = SpecialMembers.GetDescriptor(updateMethodId);
diagnostics.Add(new CSDiagnostic(new CSDiagnosticInfo(ErrorCode.ERR_MissingPredefinedMember,
memberDescriptor.DeclaringTypeMetadataName,
memberDescriptor.Name),
syntax.Location));
return(BoundBlock.SynthesizedNoLocals(syntax, @return));
}
Binder.ReportUseSiteDiagnostics(updateMethod, diagnostics, syntax);
BoundThisReference fieldReceiver = eventSymbol.IsStatic ?
null :
new BoundThisReference(syntax, thisParameter.Type.TypeSymbol)
{
WasCompilerGenerated = true
};
BoundFieldAccess boundBackingField = new BoundFieldAccess(syntax,
receiver: fieldReceiver,
fieldSymbol: eventSymbol.AssociatedField,
constantValueOpt: null)
{
WasCompilerGenerated = true
};
BoundParameter boundParameter = new BoundParameter(syntax,
parameterSymbol: accessor.Parameters[0])
{
WasCompilerGenerated = true
};
BoundExpression delegateUpdate;
MethodSymbol compareExchangeMethod = (MethodSymbol)compilation.GetWellKnownTypeMember(WellKnownMember.System_Threading_Interlocked__CompareExchange_T);
if ((object)compareExchangeMethod == null)
{
// (DelegateType)Delegate.Combine(_event, value)
delegateUpdate = BoundConversion.SynthesizedNonUserDefined(syntax,
operand: BoundCall.Synthesized(syntax,
receiverOpt: null,
method: updateMethod,
arguments: ImmutableArray.Create <BoundExpression>(boundBackingField, boundParameter)),
conversion: Conversion.ExplicitReference,
type: delegateType);
// _event = (DelegateType)Delegate.Combine(_event, value);
BoundStatement eventUpdate = new BoundExpressionStatement(syntax,
expression: new BoundAssignmentOperator(syntax,
left: boundBackingField,
right: delegateUpdate,
type: delegateType)
{
WasCompilerGenerated = true
})
{
WasCompilerGenerated = true
};
return(BoundBlock.SynthesizedNoLocals(syntax,
statements: ImmutableArray.Create <BoundStatement>(
eventUpdate,
@return)));
}
compareExchangeMethod = compareExchangeMethod.Construct(ImmutableArray.Create <TypeSymbol>(delegateType));
Binder.ReportUseSiteDiagnostics(compareExchangeMethod, diagnostics, syntax);
GeneratedLabelSymbol loopLabel = new GeneratedLabelSymbol("loop");
const int numTemps = 3;
LocalSymbol[] tmps = new LocalSymbol[numTemps];
BoundLocal[] boundTmps = new BoundLocal[numTemps];
for (int i = 0; i < numTemps; i++)
{
tmps[i] = new SynthesizedLocal(accessor, TypeSymbolWithAnnotations.Create(delegateType), SynthesizedLocalKind.LoweringTemp);
boundTmps[i] = new BoundLocal(syntax, tmps[i], null, delegateType);
}
// tmp0 = _event;
BoundStatement tmp0Init = new BoundExpressionStatement(syntax,
expression: new BoundAssignmentOperator(syntax,
left: boundTmps[0],
right: boundBackingField,
type: delegateType)
{
WasCompilerGenerated = true
})
{
WasCompilerGenerated = true
};
// LOOP:
BoundStatement loopStart = new BoundLabelStatement(syntax,
label: loopLabel)
{
WasCompilerGenerated = true
};
// tmp1 = tmp0;
BoundStatement tmp1Update = new BoundExpressionStatement(syntax,
expression: new BoundAssignmentOperator(syntax,
left: boundTmps[1],
right: boundTmps[0],
type: delegateType)
{
WasCompilerGenerated = true
})
{
WasCompilerGenerated = true
};
// (DelegateType)Delegate.Combine(tmp1, value)
delegateUpdate = BoundConversion.SynthesizedNonUserDefined(syntax,
operand: BoundCall.Synthesized(syntax,
receiverOpt: null,
method: updateMethod,
arguments: ImmutableArray.Create <BoundExpression>(boundTmps[1], boundParameter)),
conversion: Conversion.ExplicitReference,
type: delegateType);
// tmp2 = (DelegateType)Delegate.Combine(tmp1, value);
BoundStatement tmp2Update = new BoundExpressionStatement(syntax,
expression: new BoundAssignmentOperator(syntax,
left: boundTmps[2],
right: delegateUpdate,
type: delegateType)
{
WasCompilerGenerated = true
})
{
WasCompilerGenerated = true
};
// Interlocked.CompareExchange<DelegateType>(ref _event, tmp2, tmp1)
BoundExpression compareExchange = BoundCall.Synthesized(syntax,
receiverOpt: null,
method: compareExchangeMethod,
arguments: ImmutableArray.Create <BoundExpression>(boundBackingField, boundTmps[2], boundTmps[1]));
// tmp0 = Interlocked.CompareExchange<DelegateType>(ref _event, tmp2, tmp1);
BoundStatement tmp0Update = new BoundExpressionStatement(syntax,
expression: new BoundAssignmentOperator(syntax,
left: boundTmps[0],
right: compareExchange,
type: delegateType)
{
WasCompilerGenerated = true
})
{
WasCompilerGenerated = true
};
// tmp0 == tmp1 // i.e. exit when they are equal, jump to start otherwise
BoundExpression loopExitCondition = new BoundBinaryOperator(syntax,
operatorKind: BinaryOperatorKind.ObjectEqual,
left: boundTmps[0],
right: boundTmps[1],
constantValueOpt: null,
methodOpt: null,
resultKind: LookupResultKind.Viable,
type: boolType)
{
WasCompilerGenerated = true
};
// branchfalse (tmp0 == tmp1) LOOP
BoundStatement loopEnd = new BoundConditionalGoto(syntax,
condition: loopExitCondition,
jumpIfTrue: false,
label: loopLabel)
{
WasCompilerGenerated = true
};
return(new BoundBlock(syntax,
locals: tmps.AsImmutable(),
statements: ImmutableArray.Create <BoundStatement>(
tmp0Init,
loopStart,
tmp1Update,
tmp2Update,
tmp0Update,
loopEnd,
@return))
{
WasCompilerGenerated = true
});
}
private BoundExpression MakePropertyAssignment(
SyntaxNode syntax,
BoundExpression rewrittenReceiver,
PropertySymbol property,
ImmutableArray <BoundExpression> rewrittenArguments,
ImmutableArray <RefKind> argumentRefKindsOpt,
bool expanded,
ImmutableArray <int> argsToParamsOpt,
BoundExpression rewrittenRight,
TypeSymbol type,
bool used)
{
// Rewrite property assignment into call to setter.
var setMethod = property.GetOwnOrInheritedSetMethod();
if ((object)setMethod == null)
{
Debug.Assert((property as SourcePropertySymbol)?.IsAutoProperty == true,
"only autoproperties can be assignable without having setters");
var backingField = (property as SourcePropertySymbol).BackingField;
return(_factory.AssignmentExpression(
_factory.Field(rewrittenReceiver, backingField),
rewrittenRight));
}
// We have already lowered each argument, but we may need some additional rewriting for the arguments,
// such as generating a params array, re-ordering arguments based on argsToParamsOpt map, inserting arguments for optional parameters, etc.
ImmutableArray <LocalSymbol> argTemps;
rewrittenArguments = MakeArguments(
syntax,
rewrittenArguments,
property,
setMethod,
expanded,
argsToParamsOpt,
ref argumentRefKindsOpt,
out argTemps,
invokedAsExtensionMethod: false,
enableCallerInfo: ThreeState.True);
if (used)
{
// Save expression value to a temporary before calling the
// setter, and restore the temporary after the setter, so the
// assignment can be used as an embedded expression.
TypeSymbol exprType = rewrittenRight.Type;
LocalSymbol rhsTemp = _factory.SynthesizedLocal(exprType);
BoundExpression boundRhs = new BoundLocal(syntax, rhsTemp, null, exprType);
BoundExpression rhsAssignment = new BoundAssignmentOperator(
syntax,
boundRhs,
rewrittenRight,
exprType);
BoundExpression setterCall = BoundCall.Synthesized(
syntax,
rewrittenReceiver,
setMethod,
AppendToPossibleNull(rewrittenArguments, rhsAssignment));
return(new BoundSequence(
syntax,
AppendToPossibleNull(argTemps, rhsTemp),
ImmutableArray.Create(setterCall),
boundRhs,
type));
}
else
{
BoundCall setterCall = BoundCall.Synthesized(
syntax,
rewrittenReceiver,
setMethod,
AppendToPossibleNull(rewrittenArguments, rewrittenRight));
if (argTemps.IsDefaultOrEmpty)
{
return(setterCall);
}
else
{
return(new BoundSequence(
syntax,
argTemps,
ImmutableArray <BoundExpression> .Empty,
setterCall,
setMethod.ReturnType.TypeSymbol));
}
}
}
/// <summary>
/// Lowers a lock statement to a try-finally block that calls Monitor.Enter and Monitor.Exit
/// before and after the body, respectively.
/// </summary>
public override BoundNode VisitLockStatement(BoundLockStatement node)
{
LockStatementSyntax lockSyntax = (LockStatementSyntax)node.Syntax;
BoundExpression rewrittenArgument = VisitExpression(node.Argument);
BoundStatement rewrittenBody = (BoundStatement)Visit(node.Body);
TypeSymbol argumentType = rewrittenArgument.Type;
if ((object)argumentType == null)
{
// This isn't particularly elegant, but hopefully locking on null is
// not very common.
Debug.Assert(rewrittenArgument.ConstantValue == ConstantValue.Null);
argumentType = _compilation.GetSpecialType(SpecialType.System_Object);
rewrittenArgument = MakeLiteral(
rewrittenArgument.Syntax,
rewrittenArgument.ConstantValue,
argumentType); //need to have a non-null type here for TempHelpers.StoreToTemp.
}
BoundAssignmentOperator assignmentToLockTemp;
BoundLocal boundLockTemp = _factory.StoreToTemp(rewrittenArgument, out assignmentToLockTemp, syntaxOpt: lockSyntax, kind: SynthesizedLocalKind.Lock);
BoundStatement boundLockTempInit = new BoundExpressionStatement(lockSyntax, assignmentToLockTemp);
BoundExpression exitCallExpr;
MethodSymbol exitMethod;
if (TryGetWellKnownTypeMember(lockSyntax, WellKnownMember.System_Threading_Monitor__Exit, out exitMethod))
{
exitCallExpr = BoundCall.Synthesized(
lockSyntax,
null,
exitMethod,
boundLockTemp);
}
else
{
exitCallExpr = new BoundBadExpression(lockSyntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray.Create <BoundExpression>(boundLockTemp), ErrorTypeSymbol.UnknownResultType);
}
BoundStatement exitCall = new BoundExpressionStatement(lockSyntax, exitCallExpr);
MethodSymbol enterMethod;
if ((TryGetWellKnownTypeMember(lockSyntax, WellKnownMember.System_Threading_Monitor__Enter2, out enterMethod, isOptional: true) ||
TryGetWellKnownTypeMember(lockSyntax, WellKnownMember.System_Threading_Monitor__Enter, out enterMethod)) && // If we didn't find the overload introduced in .NET 4.0, then use the older one.
enterMethod.ParameterCount == 2)
{
// C# 4.0+ version
// L $lock = `argument`; // sequence point
// bool $lockTaken = false;
// try
// {
// Monitor.Enter($lock, ref $lockTaken);
// `body` // sequence point
// }
// finally
// { // hidden sequence point
// if ($lockTaken) Monitor.Exit($lock);
// }
TypeSymbol boolType = _compilation.GetSpecialType(SpecialType.System_Boolean);
BoundAssignmentOperator assignmentToLockTakenTemp;
BoundLocal boundLockTakenTemp = _factory.StoreToTemp(
MakeLiteral(rewrittenArgument.Syntax, ConstantValue.False, boolType),
store: out assignmentToLockTakenTemp,
syntaxOpt: lockSyntax,
kind: SynthesizedLocalKind.LockTaken);
BoundStatement boundLockTakenTempInit = new BoundExpressionStatement(lockSyntax, assignmentToLockTakenTemp);
BoundStatement enterCall = new BoundExpressionStatement(
lockSyntax,
BoundCall.Synthesized(
lockSyntax,
null,
enterMethod,
boundLockTemp,
boundLockTakenTemp));
exitCall = RewriteIfStatement(
lockSyntax,
boundLockTakenTemp,
exitCall,
null,
node.HasErrors);
return(new BoundBlock(
lockSyntax,
ImmutableArray.Create(boundLockTemp.LocalSymbol, boundLockTakenTemp.LocalSymbol),
ImmutableArray.Create(
InstrumentLockTargetCapture(node, boundLockTempInit),
boundLockTakenTempInit,
new BoundTryStatement(
lockSyntax,
BoundBlock.SynthesizedNoLocals(lockSyntax, ImmutableArray.Create(
enterCall,
rewrittenBody)),
ImmutableArray <BoundCatchBlock> .Empty,
BoundBlock.SynthesizedNoLocals(lockSyntax,
exitCall)))));
}
else
{
// Pre-4.0 version
// L $lock = `argument`; // sequence point
// Monitor.Enter($lock); // NB: before try-finally so we don't Exit if an exception prevents us from acquiring the lock.
// try
// {
// `body` // sequence point
// }
// finally
// {
// Monitor.Exit($lock); // hidden sequence point
// }
BoundExpression enterCallExpr;
if ((object)enterMethod != null)
{
Debug.Assert(enterMethod.ParameterCount == 1);
enterCallExpr = BoundCall.Synthesized(
lockSyntax,
null,
enterMethod,
boundLockTemp);
}
else
{
enterCallExpr = new BoundBadExpression(lockSyntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray.Create <BoundExpression>(boundLockTemp), ErrorTypeSymbol.UnknownResultType);
}
BoundStatement enterCall = new BoundExpressionStatement(
lockSyntax,
enterCallExpr);
return(new BoundBlock(
lockSyntax,
ImmutableArray.Create(boundLockTemp.LocalSymbol),
ImmutableArray.Create(
InstrumentLockTargetCapture(node, boundLockTempInit),
enterCall,
new BoundTryStatement(
lockSyntax,
BoundBlock.SynthesizedNoLocals(lockSyntax, rewrittenBody),
ImmutableArray <BoundCatchBlock> .Empty,
BoundBlock.SynthesizedNoLocals(lockSyntax, exitCall)))));
}
}
private BoundExpression LowerLiftedUnaryOperator(
UnaryOperatorKind kind,
SyntaxNode syntax,
MethodSymbol method,
BoundExpression loweredOperand,
TypeSymbol type)
{
// First, an optimization. If we know that the operand is always null then
// we can simply lower to the alternative.
BoundExpression optimized = OptimizeLiftedUnaryOperator(kind, syntax, method, loweredOperand, type);
if (optimized != null)
{
return(optimized);
}
// We do not know whether the operand is null or non-null, so we generate:
//
// S? temp = operand;
// R? r = temp.HasValue ?
// new R?(OP(temp.GetValueOrDefault())) :
// default(R?);
BoundAssignmentOperator tempAssignment;
BoundLocal boundTemp = _factory.StoreToTemp(loweredOperand, out tempAssignment);
MethodSymbol getValueOrDefault = UnsafeGetNullableMethod(syntax, boundTemp.Type, SpecialMember.System_Nullable_T_GetValueOrDefault);
// temp.HasValue
BoundExpression condition = MakeNullableHasValue(syntax, boundTemp);
// temp.GetValueOrDefault()
BoundExpression call_GetValueOrDefault = BoundCall.Synthesized(syntax, boundTemp, getValueOrDefault);
// new R?(temp.GetValueOrDefault())
BoundExpression consequence = GetLiftedUnaryOperatorConsequence(kind, syntax, method, type, call_GetValueOrDefault);
// default(R?)
BoundExpression alternative = new BoundDefaultExpression(syntax, null, type);
// temp.HasValue ?
// new R?(OP(temp.GetValueOrDefault())) :
// default(R?);
BoundExpression conditionalExpression = RewriteConditionalOperator(
syntax: syntax,
rewrittenCondition: condition,
rewrittenConsequence: consequence,
rewrittenAlternative: alternative,
constantValueOpt: null,
rewrittenType: type,
isRef: false);
// temp = operand;
// temp.HasValue ?
// new R?(OP(temp.GetValueOrDefault())) :
// default(R?);
return(new BoundSequence(
syntax: syntax,
locals: ImmutableArray.Create <LocalSymbol>(boundTemp.LocalSymbol),
sideEffects: ImmutableArray.Create <BoundExpression>(tempAssignment),
value: conditionalExpression,
type: type));
}
/// <summary>
/// Generate a thread-safe accessor for a WinRT field-like event.
///
/// Add:
/// return EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable).AddEventHandler(value);
///
/// Remove:
/// EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable).RemoveEventHandler(value);
/// </summary>
internal static BoundBlock ConstructFieldLikeEventAccessorBody_WinRT(SourceEventSymbol eventSymbol, bool isAddMethod, CSharpCompilation compilation, DiagnosticBag diagnostics)
{
CSharpSyntaxNode syntax = eventSymbol.CSharpSyntaxNode;
MethodSymbol accessor = isAddMethod ? eventSymbol.AddMethod : eventSymbol.RemoveMethod;
Debug.Assert((object)accessor != null);
FieldSymbol field = eventSymbol.AssociatedField;
Debug.Assert((object)field != null);
NamedTypeSymbol fieldType = (NamedTypeSymbol)field.Type.TypeSymbol;
Debug.Assert(fieldType.Name == "EventRegistrationTokenTable");
MethodSymbol getOrCreateMethod = (MethodSymbol)Binder.GetWellKnownTypeMember(
compilation,
WellKnownMember.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T__GetOrCreateEventRegistrationTokenTable,
diagnostics,
syntax: syntax);
if ((object)getOrCreateMethod == null)
{
Debug.Assert(diagnostics.HasAnyErrors());
return(null);
}
getOrCreateMethod = getOrCreateMethod.AsMember(fieldType);
WellKnownMember processHandlerMember = isAddMethod
? WellKnownMember.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T__AddEventHandler
: WellKnownMember.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T__RemoveEventHandler;
MethodSymbol processHandlerMethod = (MethodSymbol)Binder.GetWellKnownTypeMember(
compilation,
processHandlerMember,
diagnostics,
syntax: syntax);
if ((object)processHandlerMethod == null)
{
Debug.Assert(diagnostics.HasAnyErrors());
return(null);
}
processHandlerMethod = processHandlerMethod.AsMember(fieldType);
// _tokenTable
BoundFieldAccess fieldAccess = new BoundFieldAccess(
syntax,
field.IsStatic ? null : new BoundThisReference(syntax, accessor.ThisParameter.Type.TypeSymbol),
field,
constantValueOpt: null)
{
WasCompilerGenerated = true
};
// EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable)
BoundCall getOrCreateCall = BoundCall.Synthesized(
syntax,
receiverOpt: null,
method: getOrCreateMethod,
arg0: fieldAccess);
// value
BoundParameter parameterAccess = new BoundParameter(
syntax,
accessor.Parameters[0]);
// EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable).AddHandler(value) // or RemoveHandler
BoundCall processHandlerCall = BoundCall.Synthesized(
syntax,
receiverOpt: getOrCreateCall,
method: processHandlerMethod,
arg0: parameterAccess);
if (isAddMethod)
{
// {
// return EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable).AddHandler(value);
// }
BoundStatement returnStatement = BoundReturnStatement.Synthesized(syntax, RefKind.None, processHandlerCall);
return(BoundBlock.SynthesizedNoLocals(syntax, returnStatement));
}
else
{
// {
// EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable).RemoveHandler(value);
// return;
// }
BoundStatement callStatement = new BoundExpressionStatement(syntax, processHandlerCall);
BoundStatement returnStatement = new BoundReturnStatement(syntax, RefKind.None, expressionOpt: null);
return(BoundBlock.SynthesizedNoLocals(syntax, callStatement, returnStatement));
}
}
private BoundExpression MakeUserDefinedIncrementOperator(BoundIncrementOperator node, BoundExpression rewrittenValueToIncrement)
{
Debug.Assert((object)node.MethodOpt != null);
Debug.Assert(node.MethodOpt.ParameterCount == 1);
bool isLifted = node.OperatorKind.IsLifted();
bool @checked = node.OperatorKind.IsChecked();
BoundExpression rewrittenArgument = rewrittenValueToIncrement;
SyntaxNode syntax = node.Syntax;
TypeSymbol type = node.MethodOpt.ParameterTypes[0].TypeSymbol;
if (isLifted)
{
type = _compilation.GetSpecialType(SpecialType.core_Option_T).Construct(type);
Debug.Assert(TypeSymbol.Equals(node.MethodOpt.ParameterTypes[0].TypeSymbol, node.MethodOpt.ReturnType.TypeSymbol, TypeCompareKind.ConsiderEverything2));
}
if (!node.OperandConversion.IsIdentity)
{
rewrittenArgument = MakeConversionNode(
syntax: syntax,
rewrittenOperand: rewrittenValueToIncrement,
conversion: node.OperandConversion,
rewrittenType: type,
@checked: @checked);
}
if (!isLifted)
{
return(BoundCall.Synthesized(syntax, null, node.MethodOpt, rewrittenArgument));
}
// S? temp = operand;
// S? r = temp.HasValue ?
// new S?(op_Increment(temp.GetValueOrDefault())) :
// default(S?);
// Unlike the other unary operators, we do not attempt to optimize nullable user-defined
// increment or decrement. The operand is a variable (or property), and so we do not know if
// it is always null/never null.
BoundAssignmentOperator tempAssignment;
BoundLocal boundTemp = _factory.StoreToTemp(rewrittenArgument, out tempAssignment);
MethodSymbol getValueOrDefault = UnsafeGetNullableMethod(syntax, type, SpecialMember.System_Nullable_T_GetValueOrDefault);
MethodSymbol ctor = UnsafeGetNullableMethod(syntax, type, SpecialMember.System_Nullable_T__ctor);
// temp.HasValue
BoundExpression condition = MakeNullableHasValue(node.Syntax, boundTemp);
// temp.GetValueOrDefault()
BoundExpression call_GetValueOrDefault = BoundCall.Synthesized(syntax, boundTemp, getValueOrDefault);
// op_Increment(temp.GetValueOrDefault())
BoundExpression userDefinedCall = BoundCall.Synthesized(syntax, null, node.MethodOpt, call_GetValueOrDefault);
// new S?(op_Increment(temp.GetValueOrDefault()))
BoundExpression consequence = new BoundObjectCreationExpression(syntax, ctor, null, userDefinedCall);
// default(S?)
BoundExpression alternative = new BoundDefaultExpression(syntax, null, type);
// temp.HasValue ?
// new S?(op_Increment(temp.GetValueOrDefault())) :
// default(S?);
BoundExpression conditionalExpression = RewriteConditionalOperator(
syntax: syntax,
rewrittenCondition: condition,
rewrittenConsequence: consequence,
rewrittenAlternative: alternative,
constantValueOpt: null,
rewrittenType: type,
isRef: false);
// temp = operand;
// temp.HasValue ?
// new S?(op_Increment(temp.GetValueOrDefault())) :
// default(S?);
return(new BoundSequence(
syntax: syntax,
locals: ImmutableArray.Create <LocalSymbol>(boundTemp.LocalSymbol),
sideEffects: ImmutableArray.Create <BoundExpression>(tempAssignment),
value: conditionalExpression,
type: type));
}
private BoundStatement RewriteUsingStatementTryFinally(SyntaxNode syntax, BoundBlock tryBlock, BoundLocal local, SyntaxToken awaitKeywordOpt, AwaitableInfo awaitOpt, MethodSymbol methodOpt)
{
// SPEC: When ResourceType is a non-nullable value type, the expansion is:
// SPEC:
// SPEC: {
// SPEC: ResourceType resource = expr;
// SPEC: try { statement; }
// SPEC: finally { ((IDisposable)resource).Dispose(); }
// SPEC: }
// SPEC:
// SPEC: Otherwise, when Resource type is a nullable value type or
// SPEC: a reference type other than dynamic, the expansion is:
// SPEC:
// SPEC: {
// SPEC: ResourceType resource = expr;
// SPEC: try { statement; }
// SPEC: finally { if (resource != null) ((IDisposable)resource).Dispose(); }
// SPEC: }
// SPEC:
// SPEC: Otherwise, when ResourceType is dynamic, the expansion is:
// SPEC: {
// SPEC: dynamic resource = expr;
// SPEC: IDisposable d = (IDisposable)resource;
// SPEC: try { statement; }
// SPEC: finally { if (d != null) d.Dispose(); }
// SPEC: }
// SPEC:
// SPEC: An implementation is permitted to implement a given using statement
// SPEC: differently -- for example, for performance reasons -- as long as the
// SPEC: behavior is consistent with the above expansion.
//
// In the case of using-await statement, we'll use "IAsyncDisposable" instead of "IDisposable", "await DisposeAsync()" instead of "Dispose()"
//
// And we do in fact generate the code slightly differently than precisely how it is
// described above.
//
// First: if the type is a non-nullable value type then we do not do the
// *boxing conversion* from the resource to IDisposable. Rather, we do
// a *constrained virtual call* that elides the boxing if possible.
//
// Now, you might wonder if that is legal; isn't skipping the boxing producing
// an observable difference? Because if the value type is mutable and the Dispose
// mutates it, then skipping the boxing means that we are now mutating the original,
// not the boxed copy. But this is never observable. Either (1) we have "using(R r = x){}"
// and r is out of scope after the finally, so it is not possible to observe the mutation,
// or (2) we have "using(x) {}". But that has the semantics of "using(R temp = x){}",
// so again, we are not mutating x to begin with; we're always mutating a copy. Therefore
// it doesn't matter if we skip making *a copy of the copy*.
//
// This is what the dev10 compiler does, and we do so as well.
//
// Second: if the type is a nullable value type then we can similarly elide the boxing.
// We can generate
//
// {
// ResourceType resource = expr;
// try { statement; }
// finally { if (resource.HasValue) resource.GetValueOrDefault().Dispose(); }
// }
//
// Where again we do a constrained virtual call to Dispose, rather than boxing
// the value to IDisposable.
//
// Note that this optimization is *not* what the native compiler does; in this case
// the native compiler behavior is to test for HasValue, then *box* and convert
// the boxed value to IDisposable. There's no need to do that.
//
// Third: if we have "using(x)" and x is dynamic then obviously we need not generate
// "{ dynamic temp1 = x; IDisposable temp2 = (IDisposable) temp1; ... }". Rather, we elide
// the completely unnecessary first temporary.
Debug.Assert((awaitKeywordOpt == default) == (awaitOpt == default(AwaitableInfo)));
BoundExpression disposedExpression;
bool isNullableValueType = local.Type.IsNullableType();
if (isNullableValueType)
{
MethodSymbol getValueOrDefault = UnsafeGetNullableMethod(syntax, local.Type, SpecialMember.System_Nullable_T_GetValueOrDefault);
// local.GetValueOrDefault()
disposedExpression = BoundCall.Synthesized(syntax, local, getValueOrDefault);
}
else
{
// local
disposedExpression = local;
}
BoundExpression disposeCall = GenerateDisposeCall(syntax, disposedExpression, methodOpt, awaitOpt, awaitKeywordOpt);
// local.Dispose(); or await variant
BoundStatement disposeStatement = new BoundExpressionStatement(syntax, disposeCall);
BoundExpression ifCondition;
if (isNullableValueType)
{
// local.HasValue
ifCondition = MakeNullableHasValue(syntax, local);
}
else if (local.Type.IsValueType)
{
ifCondition = null;
}
else
{
// local != null
ifCondition = MakeNullCheck(syntax, local, BinaryOperatorKind.NotEqual);
}
BoundStatement finallyStatement;
if (ifCondition == null)
{
// local.Dispose(); or await variant
finallyStatement = disposeStatement;
}
else
{
// if (local != null) local.Dispose();
// or
// if (local.HasValue) local.GetValueOrDefault().Dispose();
// or
// await variants
finallyStatement = RewriteIfStatement(
syntax: syntax,
rewrittenCondition: ifCondition,
rewrittenConsequence: disposeStatement,
rewrittenAlternativeOpt: null,
hasErrors: false);
}
// try { ... } finally { if (local != null) local.Dispose(); }
// or
// nullable or await variants
BoundStatement tryFinally = new BoundTryStatement(
syntax: syntax,
tryBlock: tryBlock,
catchBlocks: ImmutableArray <BoundCatchBlock> .Empty,
finallyBlockOpt: BoundBlock.SynthesizedNoLocals(syntax, finallyStatement));
return(tryFinally);
}
private BoundExpression MakeNullCoalescingOperator(
SyntaxNode syntax,
BoundExpression rewrittenLeft,
BoundExpression rewrittenRight,
Conversion leftConversion,
BoundNullCoalescingOperatorResultKind resultKind,
TypeSymbol rewrittenResultType)
{
Debug.Assert(rewrittenLeft != null);
Debug.Assert(rewrittenRight != null);
Debug.Assert(leftConversion.IsValid);
Debug.Assert((object)rewrittenResultType != null);
Debug.Assert(rewrittenRight.Type.Equals(rewrittenResultType, TypeCompareKind.IgnoreDynamicAndTupleNames | TypeCompareKind.IgnoreNullableModifiersForReferenceTypes));
var isUnconstrainedTypeParameter = (object)rewrittenLeft.Type != null && !rewrittenLeft.Type.IsReferenceType && !rewrittenLeft.Type.IsValueType;
// first we can make a small optimization:
// If left is a constant then we already know whether it is null or not. If it is null then we
// can simply generate "right". If it is not null then we can simply generate
// MakeConversion(left). This does not hold when the left is an unconstrained type parameter: at runtime,
// it can be either left or right depending on the runtime type of T
if (!isUnconstrainedTypeParameter)
{
if (rewrittenLeft.IsDefaultValue())
{
return(rewrittenRight);
}
if (rewrittenLeft.ConstantValue != null)
{
Debug.Assert(!rewrittenLeft.ConstantValue.IsNull);
return(GetConvertedLeftForNullCoalescingOperator(rewrittenLeft, leftConversion, rewrittenResultType));
}
}
// string concatenation is never null.
// interpolated string lowering may introduce redundant null coalescing, which we have to remove.
if (IsStringConcat(rewrittenLeft))
{
return(GetConvertedLeftForNullCoalescingOperator(rewrittenLeft, leftConversion, rewrittenResultType));
}
// if left conversion is intrinsic implicit (always succeeds) and results in a reference type
// we can apply conversion before doing the null check that allows for a more efficient IL emit.
if (rewrittenLeft.Type.IsReferenceType &&
leftConversion.IsImplicit &&
!leftConversion.IsUserDefined)
{
if (!leftConversion.IsIdentity)
{
rewrittenLeft = MakeConversionNode(rewrittenLeft.Syntax, rewrittenLeft, leftConversion, rewrittenResultType, @checked: false);
}
return(new BoundNullCoalescingOperator(syntax, rewrittenLeft, rewrittenRight, Conversion.Identity, resultKind, rewrittenResultType));
}
if (leftConversion.IsIdentity || leftConversion.Kind == ConversionKind.ExplicitNullable)
{
var conditionalAccess = rewrittenLeft as BoundLoweredConditionalAccess;
if (conditionalAccess != null &&
(conditionalAccess.WhenNullOpt == null || NullableNeverHasValue(conditionalAccess.WhenNullOpt)))
{
var notNullAccess = NullableAlwaysHasValue(conditionalAccess.WhenNotNull);
if (notNullAccess != null)
{
var whenNullOpt = rewrittenRight;
if (whenNullOpt.Type.IsNullableType())
{
notNullAccess = conditionalAccess.WhenNotNull;
}
if (whenNullOpt.IsDefaultValue())
{
whenNullOpt = null;
}
return(conditionalAccess.Update(
conditionalAccess.Receiver,
conditionalAccess.HasValueMethodOpt,
whenNotNull: notNullAccess,
whenNullOpt: whenNullOpt,
id: conditionalAccess.Id,
type: rewrittenResultType
));
}
}
}
// Optimize left ?? right to left.GetValueOrDefault() when left is T? and right is the default value of T
if (rewrittenLeft.Type.IsNullableType() &&
RemoveIdentityConversions(rewrittenRight).IsDefaultValue() &&
rewrittenRight.Type.Equals(rewrittenLeft.Type.GetNullableUnderlyingType(), TypeCompareKind.AllIgnoreOptions) &&
TryGetNullableMethod(rewrittenLeft.Syntax, rewrittenLeft.Type, SpecialMember.System_Nullable_T_GetValueOrDefault, out MethodSymbol getValueOrDefault))
{
return(BoundCall.Synthesized(rewrittenLeft.Syntax, rewrittenLeft, getValueOrDefault));
}
// We lower left ?? right to
//
// var temp = left;
// (temp != null) ? MakeConversion(temp) : right
//
BoundAssignmentOperator tempAssignment;
BoundLocal boundTemp = _factory.StoreToTemp(rewrittenLeft, out tempAssignment);
// temp != null
BoundExpression nullCheck = MakeNullCheck(syntax, boundTemp, BinaryOperatorKind.NotEqual);
// MakeConversion(temp, rewrittenResultType)
BoundExpression convertedLeft = GetConvertedLeftForNullCoalescingOperator(boundTemp, leftConversion, rewrittenResultType);
Debug.Assert(convertedLeft.HasErrors || convertedLeft.Type.Equals(rewrittenResultType, TypeCompareKind.IgnoreDynamicAndTupleNames | TypeCompareKind.IgnoreNullableModifiersForReferenceTypes));
// (temp != null) ? MakeConversion(temp, LeftConversion) : RightOperand
BoundExpression conditionalExpression = RewriteConditionalOperator(
syntax: syntax,
rewrittenCondition: nullCheck,
rewrittenConsequence: convertedLeft,
rewrittenAlternative: rewrittenRight,
constantValueOpt: null,
rewrittenType: rewrittenResultType,
isRef: false);
Debug.Assert(conditionalExpression.ConstantValue == null); // we shouldn't have hit this else case otherwise
Debug.Assert(conditionalExpression.Type.Equals(rewrittenResultType, TypeCompareKind.IgnoreDynamicAndTupleNames | TypeCompareKind.IgnoreNullableModifiersForReferenceTypes));
return(new BoundSequence(
syntax: syntax,
locals: ImmutableArray.Create(boundTemp.LocalSymbol),
sideEffects: ImmutableArray.Create <BoundExpression>(tempAssignment),
value: conditionalExpression,
type: rewrittenResultType));
}
private BoundExpression MakeEventAccess(
SyntaxNode syntax,
BoundExpression rewrittenReceiver,
EventSymbol eventSymbol,
ConstantValue constantValueOpt,
LookupResultKind resultKind,
TypeSymbol type)
{
Debug.Assert(eventSymbol.HasAssociatedField);
FieldSymbol fieldSymbol = eventSymbol.AssociatedField;
Debug.Assert((object)fieldSymbol != null);
if (!eventSymbol.IsWindowsRuntimeEvent)
{
return(MakeFieldAccess(syntax, rewrittenReceiver, fieldSymbol, constantValueOpt, resultKind, type));
}
NamedTypeSymbol fieldType = (NamedTypeSymbol)fieldSymbol.Type.TypeSymbol;
Debug.Assert(fieldType.Name == "EventRegistrationTokenTable");
// _tokenTable
BoundFieldAccess fieldAccess = new BoundFieldAccess(
syntax,
fieldSymbol.IsStatic ? null : rewrittenReceiver,
fieldSymbol,
constantValueOpt: null)
{
WasCompilerGenerated = true
};
BoundExpression getOrCreateCall;
MethodSymbol getOrCreateMethod;
if (TryGetWellKnownTypeMember(syntax, WellKnownMember.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T__GetOrCreateEventRegistrationTokenTable, out getOrCreateMethod))
{
getOrCreateMethod = getOrCreateMethod.AsMember(fieldType);
// EventRegistrationTokenTable<Event>.GetOrCreateEventRegistrationTokenTable(ref _tokenTable)
getOrCreateCall = BoundCall.Synthesized(
syntax,
receiverOpt: null,
method: getOrCreateMethod,
arg0: fieldAccess);
}
else
{
getOrCreateCall = new BoundBadExpression(syntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray.Create <BoundExpression>(fieldAccess), ErrorTypeSymbol.UnknownResultType);
}
PropertySymbol invocationListProperty;
if (TryGetWellKnownTypeMember(syntax, WellKnownMember.System_Runtime_InteropServices_WindowsRuntime_EventRegistrationTokenTable_T__InvocationList, out invocationListProperty))
{
MethodSymbol invocationListAccessor = invocationListProperty.GetMethod;
if ((object)invocationListAccessor == null)
{
string accessorName = SourcePropertyAccessorSymbol.GetAccessorName(invocationListProperty.Name,
getNotSet: true,
isWinMdOutput: invocationListProperty.IsCompilationOutputWinMdObj());
_diagnostics.Add(new CSDiagnosticInfo(ErrorCode.ERR_MissingPredefinedMember, invocationListProperty.ContainingType, accessorName), syntax.Location);
}
else
{
invocationListAccessor = invocationListAccessor.AsMember(fieldType);
return(_factory.Call(getOrCreateCall, invocationListAccessor));
}
}
return(new BoundBadExpression(syntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray.Create(getOrCreateCall), ErrorTypeSymbol.UnknownResultType));
}