protected bool IsNullableValueAccess(EXPR pExpr, EXPR pObject)
{
Debug.Assert(pExpr != null);
return pExpr.isPROP() && (pExpr.asPROP().GetMemberGroup().GetOptionalObject() == pObject) && pObject.type.IsNullableType();
}
private EXPR ReorderArgumentsForNamedAndOptional(EXPR callingObject, EXPR pResult)
{
EXPR arguments;
AggregateType type;
MethodOrPropertySymbol methprop;
EXPRMEMGRP memgroup;
TypeArray typeArgs;
if (pResult.isCALL())
{
EXPRCALL call = pResult.asCALL();
arguments = call.GetOptionalArguments();
type = call.mwi.Ats;
methprop = call.mwi.Meth();
memgroup = call.GetMemberGroup();
typeArgs = call.mwi.TypeArgs;
}
else
{
Debug.Assert(pResult.isPROP());
EXPRPROP prop = pResult.asPROP();
arguments = prop.GetOptionalArguments();
type = prop.pwtSlot.Ats;
methprop = prop.pwtSlot.Prop();
memgroup = prop.GetMemberGroup();
typeArgs = null;
}
ArgInfos argInfo = new ArgInfos();
bool b;
argInfo.carg = ExpressionBinder.CountArguments(arguments, out b);
_binder.FillInArgInfoFromArgList(argInfo, arguments);
// We need to substitute type parameters BEFORE getting the most derived one because
// we're binding against the base method, and the derived method may change the
// generic arguments.
TypeArray parameters = SymbolLoader.GetTypeManager().SubstTypeArray(methprop.Params, type, typeArgs);
methprop = ExpressionBinder.GroupToArgsBinder.FindMostDerivedMethod(SymbolLoader, methprop, callingObject.type);
ExpressionBinder.GroupToArgsBinder.ReOrderArgsForNamedArguments(
methprop,
parameters,
type,
memgroup,
argInfo,
_semanticChecker.GetTypeManager(),
_exprFactory,
SymbolLoader);
{
EXPR pList = null;
// We reordered, so make a new list of them and set them on the constructor.
// Go backwards cause lists are right-flushed.
// Also perform the conversions to the right types.
for (int i = argInfo.carg - 1; i >= 0; i--)
{
EXPR pArg = argInfo.prgexpr[i];
// Strip the name-ness away, since we don't need it.
pArg = StripNamedArgument(pArg);
// Perform the correct conversion.
pArg = _binder.tryConvert(pArg, parameters[i]);
if (pList == null)
{
pList = pArg;
}
else
{
pList = _exprFactory.CreateList(pArg, pList);
}
}
if (pResult.isCALL())
{
pResult.asCALL().SetOptionalArguments(pList);
}
else
{
pResult.asPROP().SetOptionalArguments(pList);
}
}
return pResult;
}
// Return true if we actually report a failure.
protected bool TryReportLvalueFailure(EXPR expr, CheckLvalueKind kind)
{
Debug.Assert(expr != null);
// We have a lvalue failure. Was the reason because this field
// was marked readonly? Give special messages for this case.
bool isNested = false; // Did we recurse on a field or property to give a better error?
EXPR walk = expr;
while (true)
{
Debug.Assert(walk != null);
if (walk.isANYLOCAL_OK())
{
ReportLocalError(walk.asANYLOCAL().local, kind, isNested);
return(true);
}
EXPR pObject = null;
if (walk.isPROP())
{
// We've already reported read-only-property errors.
Debug.Assert(walk.asPROP().mwtSet != null);
pObject = walk.asPROP().GetMemberGroup().GetOptionalObject();
}
else if (walk.isFIELD())
{
EXPRFIELD field = walk.asFIELD();
if (field.fwt.Field().isReadOnly)
{
ReportReadOnlyError(field, kind, isNested);
return(true);
}
if (!field.fwt.Field().isStatic)
{
pObject = field.GetOptionalObject();
}
}
if (pObject != null && pObject.type.isStructOrEnum())
{
if (pObject.isCALL() || pObject.isPROP())
{
// assigning to RHS of method or property getter returning a value-type on the stack or
// passing RHS of method or property getter returning a value-type on the stack, as ref or out
ErrorContext.Error(ErrorCode.ERR_ReturnNotLValue, pObject.GetSymWithType());
return(true);
}
if (pObject.isCAST())
{
// An unboxing conversion.
//
// In the static compiler, we give the following error here:
// ErrorContext.Error(pObject.GetTree(), ErrorCode.ERR_UnboxNotLValue);
//
// But in the runtime, we allow this - mark that we're doing an
// unbox here, so that we gen the correct expression tree for it.
pObject.flags |= EXPRFLAG.EXF_UNBOXRUNTIME;
return(false);
}
}
// everything else
if (pObject != null && !pObject.isLvalue() && (walk.isFIELD() || (!isNested && walk.isPROP())))
{
Debug.Assert(pObject.type.isStructOrEnum());
walk = pObject;
}
else
{
ErrorContext.Error(GetStandardLvalueError(kind));
return(true);
}
isNested = true;
}
}
////////////////////////////////////////////////////////////////////////////////
// A false return means not to process the expr any further - it's totally out
// of place. For example - a method group or an anonymous method.
internal bool checkLvalue(EXPR expr, CheckLvalueKind kind)
{
if (!expr.isOK())
return false;
if (expr.isLvalue())
{
if (expr.isPROP())
{
CheckLvalueProp(expr.asPROP());
}
markFieldAssigned(expr);
return true;
}
switch (expr.kind)
{
case ExpressionKind.EK_PROP:
if (kind == CheckLvalueKind.OutParameter)
{
// passing a property as ref or out
ErrorContext.Error(ErrorCode.ERR_RefProperty);
return true;
}
if (!expr.asPROP().mwtSet)
{
// Assigning to a property without a setter.
// If we have
// bool? b = true; (bool)b = false;
// then this is realized immediately as
// b.Value = false;
// and no ExpressionKind.EK_CAST is generated. We'd rather not give a "you're writing
// to a read-only property" error in the case where the property access
// is not explicit in the source code. Fortunately in this case the
// cast is still hanging around in the parse tree, so we can look for it.
// POSSIBLE ERROR: It would be nice to also give this error for other situations
// POSSIBLE ERROR: in which the user is attempting to assign to a value, such as
// POSSIBLE ERROR: an explicit (bool)b.Value = false;
// POSSIBLE ERROR: Unfortunately we cannot use this trick in that situation because
// POSSIBLE ERROR: we've already discarded the OperatorKind.OP_CAST node. (This is an SyntaxKind.Dot).
// SPEC VIOLATION: More generally:
// SPEC VIOLATION: The spec states that the result of any cast is a value, not a
// SPEC VIOLATION: variable. Unfortunately we do not correctly implement this
// SPEC VIOLATION: and we probably should not start implementing it because this
// SPEC VIOLATION: would be a breaking change. We currently discard "no op" casts
// SPEC VIOLATION: very aggressively rather than generating an ExpressionKind.EK_CAST node.
ErrorContext.Error(ErrorCode.ERR_AssgReadonlyProp, expr.asPROP().pwtSlot);
return true;
}
break;
case ExpressionKind.EK_ARRAYLENGTH:
if (kind == CheckLvalueKind.OutParameter)
{
// passing a property as ref or out
ErrorContext.Error(ErrorCode.ERR_RefProperty);
}
else
{
// Special case, the length property of an array
ErrorContext.Error(ErrorCode.ERR_AssgReadonlyProp, GetSymbolLoader().getPredefinedMembers().GetProperty(PREDEFPROP.PP_ARRAY_LENGTH));
}
return true;
case ExpressionKind.EK_BOUNDLAMBDA:
case ExpressionKind.EK_UNBOUNDLAMBDA:
case ExpressionKind.EK_CONSTANT:
ErrorContext.Error(GetStandardLvalueError(kind));
return false;
case ExpressionKind.EK_MEMGRP:
{
ErrorCode err = (kind == CheckLvalueKind.OutParameter) ? ErrorCode.ERR_RefReadonlyLocalCause : ErrorCode.ERR_AssgReadonlyLocalCause;
ErrorContext.Error(err, expr.asMEMGRP().name, new ErrArgIds(MessageID.MethodGroup));
return false;
}
default:
break;
}
return !TryReportLvalueFailure(expr, kind);
}
