private BoundExpression BindElementAccessCore(ElementAccessExpressionSyntax node, BoundExpression expr, IList<BoundExpression> arguments, IList<string> argumentNames)
{
Debug.Assert(node != null);
Debug.Assert(expr != null);
Debug.Assert(arguments != null);
Debug.Assert(argumentNames != null);
// UNDONE: Suppose we have an indexed property P on an instance c. Suppose the
// UNDONE: type of the property is int[]. When binding c.P[123] we must
// UNDONE: treat this as an invocation of the indexed property, not as a
// UNDONE: dereference of the array returned by the property.
//if (expr.isPROP() && expr.asPROP().IsUnboundIndexedProperty() &&
// !IsPropertyBindingInsideBindIndexerContext(node.Expression))
//{
// return BindIndexerAccess(node, expr, arguments, argumentNames);
//}
var exprType = expr.GetExpressionType();
// UNDONE: Ensure that the type of the expression has members defined.
if (exprType is ArrayTypeSymbol)
{
return BindArrayAccess(node, expr, arguments, argumentNames);
}
else if (exprType is PointerTypeSymbol)
{
return BindPointerElementAccess(node, expr, arguments, argumentNames);
}
else
{
return BindIndexerAccess(node, expr, arguments, argumentNames);
}
}
private BoundExpression BindElementAccessCore(ElementAccessExpressionSyntax node, BoundExpression expr, IList <BoundExpression> arguments, IList <string> argumentNames)
{
Debug.Assert(node != null);
Debug.Assert(expr != null);
Debug.Assert(arguments != null);
Debug.Assert(argumentNames != null);
// UNDONE: Suppose we have an indexed property P on an instance c. Suppose the
// UNDONE: type of the property is int[]. When binding c.P[123] we must
// UNDONE: treat this as an invocation of the indexed property, not as a
// UNDONE: dereference of the array returned by the property.
//if (expr.isPROP() && expr.asPROP().IsUnboundIndexedProperty() &&
// !IsPropertyBindingInsideBindIndexerContext(node.Expression))
//{
// return BindIndexerAccess(node, expr, arguments, argumentNames);
//}
var exprType = expr.GetExpressionType();
// UNDONE: Ensure that the type of the expression has members defined.
if (exprType is ArrayTypeSymbol)
{
return(BindArrayAccess(node, expr, arguments, argumentNames));
}
else if (exprType is PointerTypeSymbol)
{
return(BindPointerElementAccess(node, expr, arguments, argumentNames));
}
else
{
return(BindIndexerAccess(node, expr, arguments, argumentNames));
}
}
public static string GetErrorReportingName(BoundExpression expression)
{
switch (expression.Kind)
{
case BoundKind.Literal:
if (expression.ConstantValue.IsNull)
{
return("<null>");
}
break;
case BoundKind.Lambda:
case BoundKind.UnboundLambda:
return("lambda expression"); // UNDONE: or "anonymous method"
case BoundKind.MethodGroup:
return("method group");
}
return(GetErrorReportingName(expression.GetExpressionType()));
}
private BoundExpression BindArrayAccess(ElementAccessExpressionSyntax node, BoundExpression expr, IList <BoundExpression> arguments, IList <string> argumentNames)
{
Debug.Assert(node != null);
Debug.Assert(expr != null);
Debug.Assert(arguments != null);
Debug.Assert(argumentNames != null);
// For an array access, the primary-no-array-creation-expression of the element-access must
// be a value of an array-type. Furthermore, the argument-list of an array access is not
// allowed to contain named arguments.The number of expressions in the argument-list must
// be the same as the rank of the array-type, and each expression must be of type
// int, uint, long, ulong, or must be implicitly convertible to one or more of these types.
if (argumentNames.Any(x => x != null))
{
Error(ErrorCode.ERR_NamedArgumentForArray, node);
}
var arrayType = (ArrayTypeSymbol)expr.GetExpressionType();
// Note that the spec says to determine which of {int, uint, long, ulong} *each*
// index expression is convertible to. That is not what C# 1 through 4
// did; the implementations instead determined which of those four
// types *all* of the index expressions converted to.
int rank = arrayType.Rank;
if (arguments.Count != arrayType.Rank)
{
Error(ErrorCode.ERR_BadIndexCount, node, rank);
return(BoundArrayAccess.AsError(node, expr, arguments, arrayType.ElementType));
}
var convertedArguments = arguments.Select(x => ConvertToArrayIndex(x)).ToList();
return(new BoundArrayAccess(node, expr, convertedArguments, arrayType.ElementType));
}
private BoundExpression BindArrayAccess(ElementAccessExpressionSyntax node, BoundExpression expr, IList<BoundExpression> arguments, IList<string> argumentNames)
{
Debug.Assert(node != null);
Debug.Assert(expr != null);
Debug.Assert(arguments != null);
Debug.Assert(argumentNames != null);
// For an array access, the primary-no-array-creation-expression of the element-access must
// be a value of an array-type. Furthermore, the argument-list of an array access is not
// allowed to contain named arguments.The number of expressions in the argument-list must
// be the same as the rank of the array-type, and each expression must be of type
// int, uint, long, ulong, or must be implicitly convertible to one or more of these types.
if (argumentNames.Any(x => x != null))
{
Error(ErrorCode.ERR_NamedArgumentForArray, node);
}
var arrayType = (ArrayTypeSymbol)expr.GetExpressionType();
// Note that the spec says to determine which of {int, uint, long, ulong} *each*
// index expression is convertible to. That is not what C# 1 through 4
// did; the implementations instead determined which of those four
// types *all* of the index expressions converted to.
int rank = arrayType.Rank;
if (arguments.Count != arrayType.Rank)
{
Error(ErrorCode.ERR_BadIndexCount, node, rank);
return BoundArrayAccess.AsError(node, expr, arguments, arrayType.ElementType);
}
var convertedArguments = arguments.Select(x => ConvertToArrayIndex(x)).ToList();
return new BoundArrayAccess(node, expr, convertedArguments, arrayType.ElementType);
}
public static string GetErrorReportingName(BoundExpression expression)
{
switch(expression.Kind)
{
case BoundKind.Literal:
if (expression.ConstantValue.IsNull)
return "<null>";
break;
case BoundKind.Lambda:
case BoundKind.UnboundLambda:
return "lambda expression"; // UNDONE: or "anonymous method"
case BoundKind.MethodGroup:
return "method group";
}
return GetErrorReportingName(expression.GetExpressionType());
}
