return null;
args.Add (a);
- method = Invocation.OverloadResolve (ec, (MethodGroupExpr) mg, args, loc);
+ method = Invocation.OverloadResolve (
+ ec, (MethodGroupExpr) mg, args, false, loc);
if (method == null)
return null;
e = new IntConstant (-((ShortConstant) expr).Value);
else if (expr is UShortConstant)
e = new IntConstant (-((UShortConstant) expr).Value);
+ else if (expr is SByteConstant)
+ e = new IntConstant (-((SByteConstant) expr).Value);
+ else if (expr is ByteConstant)
+ e = new IntConstant (-((ByteConstant) expr).Value);
return e;
}
case Operator.UnaryNegation:
result = TryReduceNegative (e);
- return true;
+ return result != null;
case Operator.LogicalNot:
if (expr_type != TypeManager.bool_type) {
Expression ResolveOperator (EmitContext ec)
{
- Type expr_type = Expr.Type;
+ //
+ // Step 1: Default operations on CLI native types.
+ //
+
+ // Attempt to use a constant folding operation.
+ if (Expr is Constant){
+ Expression result;
+
+ if (Reduce (ec, (Constant) Expr, out result))
+ return result;
+ }
//
- // Step 1: Perform Operator Overload location
+ // Step 2: Perform Operator Overload location
//
+ Type expr_type = Expr.Type;
Expression mg;
string op_name;
if (expr_type == null)
return null;
- //
- // Step 2: Default operations on CLI native types.
- //
-
- // Attempt to use a constant folding operation.
- if (Expr is Constant){
- Expression result;
-
- if (Reduce (ec, (Constant) Expr, out result))
- return result;
- }
-
switch (Oper){
case Operator.LogicalNot:
if (expr_type != TypeManager.bool_type) {
}
IVariable variable = Expr as IVariable;
- if (!ec.InFixedInitializer && ((variable == null) || !variable.VerifyFixed (false))) {
+ bool is_fixed = variable != null && variable.VerifyFixed (false);
+
+ if (!ec.InFixedInitializer && !is_fixed) {
Error (212, "You can only take the address of an unfixed expression inside " +
"of a fixed statement initializer");
return null;
}
-
- if (ec.InFixedInitializer && ((variable != null) && variable.VerifyFixed (false))) {
+
+ if (ec.InFixedInitializer && is_fixed) {
Error (213, "You can not fix an already fixed expression");
return null;
}
+ LocalVariableReference lr = Expr as LocalVariableReference;
+ if (lr != null){
+ if (lr.local_info.IsCaptured){
+ AnonymousMethod.Error_AddressOfCapturedVar (lr.Name, loc);
+ return null;
+ }
+ lr.local_info.AddressTaken = true;
+ lr.local_info.Used = true;
+ }
+
// According to the specs, a variable is considered definitely assigned if you take
// its address.
- if ((variable != null) && (variable.VariableInfo != null))
+ if ((variable != null) && (variable.VariableInfo != null)){
variable.VariableInfo.SetAssigned (ec);
+ }
type = TypeManager.GetPointerType (Expr.Type);
return this;
// after semantic analysis (this is so we can take the address
// of an indirection).
//
- public class Indirection : Expression, IMemoryLocation, IAssignMethod {
+ public class Indirection : Expression, IMemoryLocation, IAssignMethod, IVariable {
Expression expr;
LocalTemporary temporary;
bool prepared;
{
return "*(" + expr + ")";
}
+
+ #region IVariable Members
+
+ public VariableInfo VariableInfo {
+ get {
+ return null;
+ }
+ }
+
+ public bool VerifyFixed (bool is_expression)
+ {
+ return true;
+ }
+
+ #endregion
}
/// <summary>
return null;
} else {
- expr.Error_UnexpectedKind ("variable, indexer or property access");
+ expr.Error_UnexpectedKind ("variable, indexer or property access", loc);
return null;
}
/// size.
/// </remarks>
public abstract class Probe : Expression {
- public readonly Expression ProbeType;
+ public Expression ProbeType;
protected Expression expr;
protected Type probe_type;
public override Expression DoResolve (EmitContext ec)
{
- probe_type = ec.DeclSpace.ResolveType (ProbeType, false, loc);
-
- if (probe_type == null)
+ TypeExpr texpr = ProbeType.ResolveAsTypeTerminal (ec, false);
+ if (texpr == null)
return null;
+ probe_type = texpr.ResolveType (ec);
CheckObsoleteAttribute (probe_type);
if (expr == null)
return null;
+ if (expr.Type.IsPointer) {
+ Report.Error (244, loc, "\"is\" or \"as\" are not valid on pointer types");
+ return null;
+ }
return this;
}
}
warning_never_matches = true;
}
- if (RootContext.WarningLevel >= 1){
- if (warning_always_matches)
- Warning (183, "The expression is always of type `" +
- TypeManager.CSharpName (probe_type) + "'");
- else if (warning_never_matches){
- if (!(probe_type.IsInterface || expr.Type.IsInterface))
- Warning (184,
- "The expression is never of type `" +
- TypeManager.CSharpName (probe_type) + "'");
- }
+ if (warning_always_matches)
+ Warning (183, "The given expression is always of the provided ('{0}') type", TypeManager.CSharpName (probe_type));
+ else if (warning_never_matches){
+ if (!(probe_type.IsInterface || expr.Type.IsInterface))
+ Warning (184, "The given expression is never of the provided ('{0}') type", TypeManager.CSharpName (probe_type));
}
return this;
if (expr == null)
return null;
- type = ec.DeclSpace.ResolveType (target_type, false, Location);
-
- if (type == null)
+ TypeExpr target = target_type.ResolveAsTypeTerminal (ec, false);
+ if (target == null)
return null;
+ type = target.ResolveType (ec);
+
CheckObsoleteAttribute (type);
+ if (type.IsAbstract && type.IsSealed) {
+ Report.Error (716, loc, "Cannot convert to static type '{0}'", TypeManager.CSharpName (type));
+ return null;
+ }
+
eclass = ExprClass.Value;
if (expr is Constant){
// Special cases: string comapred to null
//
if (oper == Operator.Equality || oper == Operator.Inequality){
- if ((l == TypeManager.string_type && (right is NullLiteral)) ||
- (r == TypeManager.string_type && (left is NullLiteral))){
+ if ((!TypeManager.IsValueType (l) && r == TypeManager.null_type) ||
+ (!TypeManager.IsValueType (r) && l == TypeManager.null_type)) {
Type = TypeManager.bool_type;
return this;
args.Add (new Argument (left, Argument.AType.Expression));
args.Add (new Argument (right, Argument.AType.Expression));
- MethodBase method = Invocation.OverloadResolve (ec, union, args, Location.Null);
+ MethodBase method = Invocation.OverloadResolve (
+ ec, union, args, true, Location.Null);
+
if (method != null) {
MethodInfo mi = (MethodInfo) method;
//
// Also, a standard conversion must exist from either one
//
- if (!(Convert.ImplicitStandardConversionExists (left, r) ||
- Convert.ImplicitStandardConversionExists (right, l))){
+ if (!(Convert.ImplicitStandardConversionExists (ec, left, r) ||
+ Convert.ImplicitStandardConversionExists (ec, right, l))){
Error_OperatorCannotBeApplied ();
return null;
}
//
if (oper == Operator.Addition || oper == Operator.Subtraction) {
if (l.IsSubclassOf (TypeManager.delegate_type)){
- if (right.eclass == ExprClass.MethodGroup && RootContext.V2){
- Expression tmp = Convert.ImplicitConversionRequired (ec, right, l, loc);
- if (tmp == null)
- return null;
- right = tmp;
- r = right.Type;
+ if (((right.eclass == ExprClass.MethodGroup) ||
+ (r == TypeManager.anonymous_method_type))){
+ if ((RootContext.Version != LanguageVersion.ISO_1)){
+ Expression tmp = Convert.ImplicitConversionRequired (ec, right, l, loc);
+ if (tmp == null)
+ return null;
+ right = tmp;
+ r = right.Type;
+ }
}
-
+
if (r.IsSubclassOf (TypeManager.delegate_type)){
MethodInfo method;
ArrayList args = new ArrayList (2);
if (r == l)
return new PointerArithmetic (
false, left, right, TypeManager.int64_type,
- loc);
+ loc).Resolve (ec);
} else {
Expression t = Make32or64 (ec, right);
if (t != null)
- return new PointerArithmetic (oper == Operator.Addition, left, t, l, loc);
+ return new PointerArithmetic (oper == Operator.Addition, left, t, l, loc).Resolve (ec);
}
} else if (r.IsPointer && oper == Operator.Addition){
Expression t = Make32or64 (ec, left);
if (t != null)
- return new PointerArithmetic (true, right, t, r, loc);
+ return new PointerArithmetic (true, right, t, r, loc).Resolve (ec);
}
}
}
} else
left = left.Resolve (ec);
- right = right.Resolve (ec);
- if (left == null || right == null)
+ if (left == null)
+ return null;
+
+ Constant lc = left as Constant;
+ if (lc != null && lc.Type == TypeManager.bool_type &&
+ ((oper == Operator.LogicalAnd && (bool)lc.GetValue () == false) ||
+ (oper == Operator.LogicalOr && (bool)lc.GetValue () == true))) {
+
+ // TODO: make a sense to resolve unreachable expression as we do for statement
+ Report.Warning (429, 4, loc, "Unreachable expression code detected");
+ return left;
+ }
+
+ right = right.Resolve (ec);
+ if (right == null)
return null;
eclass = ExprClass.Value;
Constant rc = right as Constant;
- Constant lc = left as Constant;
-
if (rc != null & lc != null){
Expression e = ConstantFold.BinaryFold (
ec, oper, lc, rc, loc);
public class StringConcat : Expression {
ArrayList operands;
bool invalid = false;
-
+ bool emit_conv_done = false;
+ //
+ // Are we also concating objects?
+ //
+ bool is_strings_only = true;
public StringConcat (EmitContext ec, Location loc, Expression left, Expression right)
{
{
MethodInfo concat_method = null;
- //
- // Are we also concating objects?
- //
- bool is_strings_only = true;
-
//
// Do conversion to arguments; check for strings only
//
- for (int i = 0; i < operands.Count; i ++) {
- Expression e = (Expression) operands [i];
- is_strings_only &= e.Type == TypeManager.string_type;
- }
- for (int i = 0; i < operands.Count; i ++) {
- Expression e = (Expression) operands [i];
+ // This can get called multiple times, so we have to deal with that.
+ if (!emit_conv_done) {
+ emit_conv_done = true;
+ for (int i = 0; i < operands.Count; i ++) {
+ Expression e = (Expression) operands [i];
+ is_strings_only &= e.Type == TypeManager.string_type;
+ }
- if (! is_strings_only && e.Type == TypeManager.string_type) {
- // need to make sure this is an object, because the EmitParams
- // method might look at the type of this expression, see it is a
- // string and emit a string [] when we want an object [];
+ for (int i = 0; i < operands.Count; i ++) {
+ Expression e = (Expression) operands [i];
- e = Convert.ImplicitConversion (ec, e, TypeManager.object_type, loc);
+ if (! is_strings_only && e.Type == TypeManager.string_type) {
+ // need to make sure this is an object, because the EmitParams
+ // method might look at the type of this expression, see it is a
+ // string and emit a string [] when we want an object [];
+
+ e = new EmptyCast (e, TypeManager.object_type);
+ }
+ operands [i] = new Argument (e, Argument.AType.Expression);
}
- operands [i] = new Argument (e, Argument.AType.Expression);
}
//
ArrayList arguments = new ArrayList ();
arguments.Add (new Argument (left_temp, Argument.AType.Expression));
arguments.Add (new Argument (right, Argument.AType.Expression));
- method = Invocation.OverloadResolve (ec, (MethodGroupExpr) operator_group, arguments, loc) as MethodInfo;
+ method = Invocation.OverloadResolve (
+ ec, (MethodGroupExpr) operator_group, arguments, false, loc)
+ as MethodInfo;
if ((method == null) || (method.ReturnType != type)) {
Error19 ();
return null;
Label false_target = ig.DefineLabel ();
Label end_target = ig.DefineLabel ();
- ig.Emit (OpCodes.Nop);
-
left.Emit (ec);
left_temp.Store (ec);
ig.MarkLabel (false_target);
op.Emit (ec);
ig.MarkLabel (end_target);
-
- ig.Emit (OpCodes.Nop);
}
}
public PointerArithmetic (bool is_addition, Expression l, Expression r, Type t, Location loc)
{
type = t;
- eclass = ExprClass.Variable;
this.loc = loc;
left = l;
right = r;
public override Expression DoResolve (EmitContext ec)
{
- //
- // We are born fully resolved
- //
+ eclass = ExprClass.Variable;
+
+ if (left.Type == TypeManager.void_ptr_type) {
+ Error (242, "The operation in question is undefined on void pointers");
+ return null;
+ }
+
return this;
}
//
left.Emit (ec);
ig.Emit (OpCodes.Conv_I);
- right.Emit (ec);
- if (size != 1){
- if (size == 0)
- ig.Emit (OpCodes.Sizeof, element);
- else
- IntLiteral.EmitInt (ig, size);
- if (rtype == TypeManager.int64_type)
- ig.Emit (OpCodes.Conv_I8);
- else if (rtype == TypeManager.uint64_type)
- ig.Emit (OpCodes.Conv_U8);
- ig.Emit (OpCodes.Mul);
- ig.Emit (OpCodes.Conv_I);
+
+ Constant right_const = right as Constant;
+ if (right_const != null && size != 0) {
+ Expression ex = ConstantFold.BinaryFold (ec, Binary.Operator.Multiply, new IntConstant (size), right_const, loc);
+ if (ex == null)
+ return;
+ ex.Emit (ec);
+ } else {
+ right.Emit (ec);
+ if (size != 1){
+ if (size == 0)
+ ig.Emit (OpCodes.Sizeof, element);
+ else
+ IntLiteral.EmitInt (ig, size);
+ if (rtype == TypeManager.int64_type)
+ ig.Emit (OpCodes.Conv_I8);
+ else if (rtype == TypeManager.uint64_type)
+ ig.Emit (OpCodes.Conv_U8);
+ ig.Emit (OpCodes.Mul);
+ }
}
+
+ if (rtype == TypeManager.int64_type || rtype == TypeManager.uint64_type)
+ ig.Emit (OpCodes.Conv_I);
+
if (is_add)
ig.Emit (OpCodes.Add);
else
Type true_type = trueExpr.Type;
Type false_type = falseExpr.Type;
- if (trueExpr is NullLiteral){
- type = false_type;
- return this;
- } else if (falseExpr is NullLiteral){
- type = true_type;
- return this;
- }
-
//
// First, if an implicit conversion exists from trueExpr
// to falseExpr, then the result type is of type falseExpr.Type
}
}
+ // Dead code optimalization
if (expr is BoolConstant){
BoolConstant bc = (BoolConstant) expr;
- if (bc.Value)
- return trueExpr;
- else
- return falseExpr;
+ Report.Warning (429, 4, bc.Value ? falseExpr.Location : trueExpr.Location, "Unreachable expression code detected");
+ return bc.Value ? trueExpr : falseExpr;
}
return this;
public class LocalVariableReference : Expression, IAssignMethod, IMemoryLocation, IVariable {
public readonly string Name;
public readonly Block Block;
- LocalInfo local_info;
+ public LocalInfo local_info;
bool is_readonly;
+ bool prepared;
+ LocalTemporary temp;
public LocalVariableReference (Block block, string name, Location l)
{
eclass = ExprClass.Variable;
}
+ //
// Setting `is_readonly' to false will allow you to create a writable
// reference to a read-only variable. This is used by foreach and using.
+ //
public LocalVariableReference (Block block, string name, Location l,
LocalInfo local_info, bool is_readonly)
: this (block, name, l)
}
public VariableInfo VariableInfo {
- get { return local_info.VariableInfo; }
+ get {
+ return local_info.VariableInfo;
+ }
}
public bool IsReadOnly {
}
}
- protected void DoResolveBase (EmitContext ec)
+ protected Expression DoResolveBase (EmitContext ec, Expression lvalue_right_side)
{
if (local_info == null) {
local_info = Block.GetLocalInfo (Name);
+
+ // is out param
+ if (lvalue_right_side == EmptyExpression.Null)
+ local_info.Used = true;
+
is_readonly = local_info.ReadOnly;
}
type = local_info.VariableType;
-#if false
- if (ec.InAnonymousMethod)
- Block.LiftVariable (local_info);
-#endif
- }
- protected Expression DoResolve (EmitContext ec, bool is_lvalue)
- {
+ VariableInfo variable_info = local_info.VariableInfo;
+ if (lvalue_right_side != null){
+ if (is_readonly){
+ Error (1604, "cannot assign to `" + Name + "' because it is readonly");
+ return null;
+ }
+
+ if (variable_info != null)
+ variable_info.SetAssigned (ec);
+ }
+
Expression e = Block.GetConstantExpression (Name);
if (e != null) {
local_info.Used = true;
return e.Resolve (ec);
}
- VariableInfo variable_info = local_info.VariableInfo;
if ((variable_info != null) && !variable_info.IsAssigned (ec, loc))
return null;
- if (!is_lvalue)
+ if (lvalue_right_side == null)
local_info.Used = true;
- if (local_info.LocalBuilder == null)
- return ec.RemapLocal (local_info);
-
+ if (ec.CurrentAnonymousMethod != null){
+ //
+ // If we are referencing a variable from the external block
+ // flag it for capturing
+ //
+ if (local_info.Block.Toplevel != ec.CurrentBlock.Toplevel){
+ if (local_info.AddressTaken){
+ AnonymousMethod.Error_AddressOfCapturedVar (local_info.Name, loc);
+ return null;
+ }
+ ec.CaptureVariable (local_info);
+ }
+ }
+
return this;
}
public override Expression DoResolve (EmitContext ec)
{
- DoResolveBase (ec);
-
- return DoResolve (ec, false);
+ return DoResolveBase (ec, null);
}
override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
- DoResolveBase (ec);
-
- VariableInfo variable_info = local_info.VariableInfo;
- if (variable_info != null)
- variable_info.SetAssigned (ec);
-
- Expression e = DoResolve (ec, true);
-
- if (e == null)
- return null;
-
- if (is_readonly){
- Error (1604, "cannot assign to `" + Name + "' because it is readonly");
- return null;
- }
-
- CheckObsoleteAttribute (e.Type);
-
- if (local_info.LocalBuilder == null)
- return ec.RemapLocalLValue (local_info, right_side);
+ Expression ret = DoResolveBase (ec, right_side);
+ if (ret != null)
+ CheckObsoleteAttribute (ret.Type);
- return this;
+ return ret;
}
public bool VerifyFixed (bool is_expression)
{
ILGenerator ig = ec.ig;
- ig.Emit (OpCodes.Ldloc, local_info.LocalBuilder);
+ if (local_info.FieldBuilder == null){
+ //
+ // A local variable on the local CLR stack
+ //
+ ig.Emit (OpCodes.Ldloc, local_info.LocalBuilder);
+ } else {
+ //
+ // A local variable captured by anonymous methods.
+ //
+ if (!prepared)
+ ec.EmitCapturedVariableInstance (local_info);
+
+ ig.Emit (OpCodes.Ldfld, local_info.FieldBuilder);
+ }
}
public void Emit (EmitContext ec, bool leave_copy)
{
Emit (ec);
- if (leave_copy)
+ if (leave_copy){
ec.ig.Emit (OpCodes.Dup);
+ if (local_info.FieldBuilder != null){
+ temp = new LocalTemporary (ec, Type);
+ temp.Store (ec);
+ }
+ }
}
public void EmitAssign (EmitContext ec, Expression source, bool leave_copy, bool prepare_for_load)
{
- source.Emit (ec);
- if (leave_copy)
- ec.ig.Emit (OpCodes.Dup);
- ec.ig.Emit (OpCodes.Stloc, local_info.LocalBuilder);
+ ILGenerator ig = ec.ig;
+ prepared = prepare_for_load;
+
+ if (local_info.FieldBuilder == null){
+ //
+ // A local variable on the local CLR stack
+ //
+ if (local_info.LocalBuilder == null)
+ throw new Exception ("This should not happen: both Field and Local are null");
+
+ source.Emit (ec);
+ if (leave_copy)
+ ec.ig.Emit (OpCodes.Dup);
+ ig.Emit (OpCodes.Stloc, local_info.LocalBuilder);
+ } else {
+ //
+ // A local variable captured by anonymous methods or itereators.
+ //
+ ec.EmitCapturedVariableInstance (local_info);
+
+ if (prepare_for_load)
+ ig.Emit (OpCodes.Dup);
+ source.Emit (ec);
+ if (leave_copy){
+ ig.Emit (OpCodes.Dup);
+ temp = new LocalTemporary (ec, Type);
+ temp.Store (ec);
+ }
+ ig.Emit (OpCodes.Stfld, local_info.FieldBuilder);
+ if (temp != null)
+ temp.Emit (ec);
+ }
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
ILGenerator ig = ec.ig;
-
- ig.Emit (OpCodes.Ldloca, local_info.LocalBuilder);
+
+ if (local_info.FieldBuilder == null){
+ //
+ // A local variable on the local CLR stack
+ //
+ ig.Emit (OpCodes.Ldloca, local_info.LocalBuilder);
+ } else {
+ //
+ // A local variable captured by anonymous methods or iterators
+ //
+ ec.EmitCapturedVariableInstance (local_info);
+ ig.Emit (OpCodes.Ldflda, local_info.FieldBuilder);
+ }
}
public override string ToString ()
VariableInfo vi;
public Parameter.Modifier mod;
public bool is_ref, is_out, prepared;
+
+ public bool IsOut {
+ get {
+ return is_out;
+ }
+ }
+
+ public bool IsRef {
+ get {
+ return is_ref;
+ }
+ }
+
LocalTemporary temp;
public ParameterReference (Parameters pars, Block block, int idx, string name, Location loc)
public bool IsAssigned (EmitContext ec, Location loc)
{
- if (!ec.DoFlowAnalysis || !is_out ||
- ec.CurrentBranching.IsAssigned (vi))
+ if (!ec.DoFlowAnalysis || !is_out || ec.CurrentBranching.IsAssigned (vi))
return true;
Report.Error (165, loc,
public bool IsFieldAssigned (EmitContext ec, string field_name, Location loc)
{
- if (!ec.DoFlowAnalysis || !is_out ||
- ec.CurrentBranching.IsFieldAssigned (vi, field_name))
+ if (!ec.DoFlowAnalysis || !is_out || ec.CurrentBranching.IsFieldAssigned (vi, field_name))
return true;
Report.Error (170, loc,
ec.CurrentBranching.SetAssigned (vi);
}
- public void SetFieldAssigned (EmitContext ec, string field_name)
+ public void SetFieldAssigned (EmitContext ec, string field_name)
{
if (is_out && ec.DoFlowAnalysis)
ec.CurrentBranching.SetFieldAssigned (vi, field_name);
protected void DoResolveBase (EmitContext ec)
{
- type = pars.GetParameterInfo (ec.DeclSpace, idx, out mod);
+ type = pars.GetParameterInfo (ec, idx, out mod);
is_ref = (mod & Parameter.Modifier.ISBYREF) != 0;
is_out = (mod & Parameter.Modifier.OUT) != 0;
eclass = ExprClass.Variable;
if (is_out)
vi = block.ParameterMap [idx];
+
+ if (ec.CurrentAnonymousMethod != null){
+ if (is_ref){
+ Report.Error (1628, Location,
+ "Can not reference a ref or out parameter in an anonymous method");
+ return;
+ }
+
+ //
+ // If we are referencing the parameter from the external block
+ // flag it for capturing
+ //
+ //Console.WriteLine ("Is parameter `{0}' local? {1}", name, block.IsLocalParameter (name));
+ if (!block.IsLocalParameter (name)){
+ ec.CaptureParameter (name, type, idx);
+ }
+ }
}
//
arg_idx++;
EmitLdArg (ig, arg_idx);
+
+ //
+ // FIXME: Review for anonymous methods
+ //
}
public override void Emit (EmitContext ec)
{
+ if (ec.HaveCaptureInfo && ec.IsParameterCaptured (name)){
+ ec.EmitParameter (name);
+ return;
+ }
+
Emit (ec, false);
}
public void Emit (EmitContext ec, bool leave_copy)
{
ILGenerator ig = ec.ig;
-
int arg_idx = idx;
if (!ec.IsStatic)
public void EmitAssign (EmitContext ec, Expression source, bool leave_copy, bool prepare_for_load)
{
+ if (ec.HaveCaptureInfo && ec.IsParameterCaptured (name)){
+ ec.EmitAssignParameter (name, source, leave_copy, prepare_for_load);
+ return;
+ }
+
ILGenerator ig = ec.ig;
int arg_idx = idx;
public void AddressOf (EmitContext ec, AddressOp mode)
{
+ if (ec.HaveCaptureInfo && ec.IsParameterCaptured (name)){
+ ec.EmitAddressOfParameter (name);
+ return;
+ }
+
int arg_idx = idx;
if (!ec.IsStatic)
if (Expr == null)
return false;
+ if (!ec.IsConstructor) {
+ FieldExpr fe = Expr as FieldExpr;
+ if (fe != null && fe.FieldInfo.IsInitOnly) {
+ if (fe.FieldInfo.IsStatic)
+ Report.Error (199, loc, "A static readonly field cannot be passed ref or out (except in a static constructor)");
+ else
+ Report.Error (192, loc, "A readonly field cannot be passed ref or out (except in a constructor)");
+ return false;
+ }
+ }
Expr = Expr.ResolveLValue (ec, Expr);
} else if (ArgType == AType.Out)
- Expr = Expr.ResolveLValue (ec, new EmptyExpression ());
+ Expr = Expr.ResolveLValue (ec, EmptyExpression.Null);
else
Expr = Expr.Resolve (ec);
if (instance.GetType () != typeof (This)){
if (fe.InstanceExpression.Type.IsSubclassOf (TypeManager.mbr_type)){
- Report.Error (197, loc,
- "Can not pass a type that derives from MarshalByRefObject with out or ref");
+ Report.SymbolRelatedToPreviousError (fe.InstanceExpression.Type);
+ Report.Error (197, loc, "Cannot pass '{0}' as ref or out or take its address because it is a member of a marshal-by-reference class",
+ fe.Name);
return false;
}
}
if (Expr is ParameterReference){
ParameterReference pr = (ParameterReference) Expr;
- if (pr.is_ref)
+ if (pr.IsRef)
pr.EmitLoad (ec);
else {
pr.AddressOf (ec, mode);
}
} else {
- ((IMemoryLocation)Expr).AddressOf (ec, mode);
+ if (Expr is IMemoryLocation)
+ ((IMemoryLocation) Expr).AddressOf (ec, mode);
+ else {
+ Report.Error (
+ 1510, Expr.Location,
+ "An lvalue is required as an argument to out or ref");
+ return;
+ }
}
} else
Expr.Emit (ec);
Expression expr;
MethodBase method = null;
- bool is_base;
static Hashtable method_parameter_cache;
/// <summary>
/// Determines "better conversion" as specified in 7.4.2.3
///
- /// Returns : 1 if a->p is better
- /// 0 if a->q or neither is better
+ /// Returns : p if a->p is better,
+ /// q if a->q is better,
+ /// null if neither is better
/// </summary>
- static int BetterConversion (EmitContext ec, Argument a, Type p, Type q, Location loc)
+ static Type BetterConversion (EmitContext ec, Argument a, Type p, Type q, Location loc)
{
Type argument_type = a.Type;
Expression argument_expr = a.Expr;
throw new Exception ("Expression of type " + a.Expr +
" does not resolve its type");
- //
- // This is a special case since csc behaves this way.
- //
- if (argument_expr is NullLiteral &&
- p == TypeManager.string_type &&
- q == TypeManager.object_type)
- return 1;
- else if (argument_expr is NullLiteral &&
- p == TypeManager.object_type &&
- q == TypeManager.string_type)
- return 0;
-
- //
- // csc behaves this way so we emulate it. Basically, if the argument
- // is null and one of the types to compare is 'object' and the other
- // is a reference type, we prefer the other.
- //
- // I can't find this anywhere in the spec but we can interpret this
- // to mean that null can be of any type you wish in such a context
- //
- if (p != null && q != null) {
- if (argument_expr is NullLiteral &&
- !p.IsValueType &&
- q == TypeManager.object_type)
- return 1;
- else if (argument_expr is NullLiteral &&
- !q.IsValueType &&
- p == TypeManager.object_type)
- return 0;
- }
-
+ if (p == null || q == null)
+ throw new InternalErrorException ("BetterConversion Got a null conversion");
+
if (p == q)
- return 0;
-
+ return null;
+
+ if (argument_expr is NullLiteral) {
+ //
+ // If the argument is null and one of the types to compare is 'object' and
+ // the other is a reference type, we prefer the other.
+ //
+ // This follows from the usual rules:
+ // * There is an implicit conversion from 'null' to type 'object'
+ // * There is an implicit conversion from 'null' to any reference type
+ // * There is an implicit conversion from any reference type to type 'object'
+ // * There is no implicit conversion from type 'object' to other reference types
+ // => Conversion of 'null' to a reference type is better than conversion to 'object'
+ //
+ // FIXME: This probably isn't necessary, since the type of a NullLiteral is the
+ // null type. I think it used to be 'object' and thus needed a special
+ // case to avoid the immediately following two checks.
+ //
+ if (!p.IsValueType && q == TypeManager.object_type)
+ return p;
+ if (!q.IsValueType && p == TypeManager.object_type)
+ return q;
+ }
+
if (argument_type == p)
- return 1;
+ return p;
if (argument_type == q)
- return 0;
-
- if (q == null) {
- Expression tmp = Convert.ImplicitConversion (ec, argument_expr, p, loc);
-
- if (tmp != null)
- return 1;
- else
- return 0;
- }
+ return q;
Expression p_tmp = new EmptyExpression (p);
Expression q_tmp = new EmptyExpression (q);
-
- if (Convert.ImplicitConversionExists (ec, p_tmp, q) == true &&
- Convert.ImplicitConversionExists (ec, q_tmp, p) == false)
- return 1;
+
+ bool p_to_q = Convert.ImplicitConversionExists (ec, p_tmp, q);
+ bool q_to_p = Convert.ImplicitConversionExists (ec, q_tmp, p);
+
+ if (p_to_q && !q_to_p)
+ return p;
+
+ if (q_to_p && !p_to_q)
+ return q;
if (p == TypeManager.sbyte_type)
if (q == TypeManager.byte_type || q == TypeManager.ushort_type ||
q == TypeManager.uint32_type || q == TypeManager.uint64_type)
- return 1;
+ return p;
+ if (q == TypeManager.sbyte_type)
+ if (p == TypeManager.byte_type || p == TypeManager.ushort_type ||
+ p == TypeManager.uint32_type || p == TypeManager.uint64_type)
+ return q;
if (p == TypeManager.short_type)
if (q == TypeManager.ushort_type || q == TypeManager.uint32_type ||
q == TypeManager.uint64_type)
- return 1;
+ return p;
+ if (q == TypeManager.short_type)
+ if (p == TypeManager.ushort_type || p == TypeManager.uint32_type ||
+ p == TypeManager.uint64_type)
+ return q;
if (p == TypeManager.int32_type)
if (q == TypeManager.uint32_type || q == TypeManager.uint64_type)
- return 1;
+ return p;
+ if (q == TypeManager.int32_type)
+ if (p == TypeManager.uint32_type || p == TypeManager.uint64_type)
+ return q;
if (p == TypeManager.int64_type)
if (q == TypeManager.uint64_type)
- return 1;
+ return p;
+ if (q == TypeManager.int64_type)
+ if (p == TypeManager.uint64_type)
+ return q;
- return 0;
+ return null;
}
/// <summary>
/// </summary>
/// <remarks>
/// Returns an integer indicating :
- /// 0 if candidate ain't better
- /// 1 if candidate is better than the current best match
+ /// false if candidate ain't better
+ /// true if candidate is better than the current best match
/// </remarks>
- static int BetterFunction (EmitContext ec, ArrayList args,
- MethodBase candidate, bool candidate_params,
- MethodBase best, bool best_params,
- Location loc)
+ static bool BetterFunction (EmitContext ec, ArrayList args, int argument_count,
+ MethodBase candidate, bool candidate_params,
+ MethodBase best, bool best_params, Location loc)
{
ParameterData candidate_pd = GetParameterData (candidate);
- ParameterData best_pd;
- int argument_count;
+ ParameterData best_pd = GetParameterData (best);
- if (args == null)
- argument_count = 0;
- else
- argument_count = args.Count;
-
int cand_count = candidate_pd.Count;
//
// Trim (); is better than Trim (params char[] chars);
//
if (cand_count == 0 && argument_count == 0)
- return best == null || best_params ? 1 : 0;
+ return !candidate_params && best_params;
if ((candidate_pd.ParameterModifier (cand_count - 1) != Parameter.Modifier.PARAMS) &&
(candidate_pd.ParameterModifier (cand_count - 1) != Parameter.Modifier.ARGLIST))
if (cand_count != argument_count)
- return 0;
-
- if (best == null) {
- int x = 0;
-
- if (argument_count == 0 && cand_count == 1 &&
- candidate_pd.ParameterModifier (cand_count - 1) == Parameter.Modifier.PARAMS)
- return 1;
-
- for (int j = 0; j < argument_count; ++j) {
-
- Argument a = (Argument) args [j];
- Type t = candidate_pd.ParameterType (j);
-
- if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
- if (candidate_params)
- t = TypeManager.GetElementType (t);
-
- x = BetterConversion (ec, a, t, null, loc);
-
- if (x <= 0)
- break;
- }
-
- if (x > 0)
- return 1;
- else
- return 0;
- }
-
- best_pd = GetParameterData (best);
+ return false;
- int rating1 = 0, rating2 = 0;
-
+ bool better_at_least_one = false;
for (int j = 0; j < argument_count; ++j) {
- int x, y;
-
Argument a = (Argument) args [j];
- Type ct = candidate_pd.ParameterType (j);
- Type bt = best_pd.ParameterType (j);
+ Type ct = TypeManager.TypeToCoreType (candidate_pd.ParameterType (j));
+ Type bt = TypeManager.TypeToCoreType (best_pd.ParameterType (j));
if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
if (candidate_params)
if (best_params)
bt = TypeManager.GetElementType (bt);
- x = BetterConversion (ec, a, ct, bt, loc);
- y = BetterConversion (ec, a, bt, ct, loc);
+ Type better = BetterConversion (ec, a, ct, bt, loc);
- if (x < y)
- return 0;
-
- rating1 += x;
- rating2 += y;
+ // for each argument, the conversion to 'ct' should be no worse than
+ // the conversion to 'bt'.
+ if (better == bt)
+ return false;
+
+ // for at least one argument, the conversion to 'ct' should be better than
+ // the conversion to 'bt'.
+ if (better == ct)
+ better_at_least_one = true;
}
//
// force it to select the candidate
//
if (!candidate_params && best_params && cand_count == argument_count)
- return 1;
+ return true;
- if (rating1 > rating2)
- return 1;
- else
- return 0;
+ return better_at_least_one;
}
public static string FullMethodDesc (MethodBase mb)
return union;
}
+ static bool IsParamsMethodApplicable (EmitContext ec, MethodGroupExpr me,
+ ArrayList arguments, int arg_count,
+ ref MethodBase candidate)
+ {
+ return IsParamsMethodApplicable (
+ ec, me, arguments, arg_count, false, ref candidate) ||
+ IsParamsMethodApplicable (
+ ec, me, arguments, arg_count, true, ref candidate);
+
+
+ }
+
+ static bool IsParamsMethodApplicable (EmitContext ec, MethodGroupExpr me,
+ ArrayList arguments, int arg_count,
+ bool do_varargs, ref MethodBase candidate)
+ {
+ return IsParamsMethodApplicable (
+ ec, arguments, arg_count, candidate, do_varargs);
+ }
+
/// <summary>
/// Determines if the candidate method, if a params method, is applicable
/// in its expanded form to the given set of arguments
/// </summary>
static bool IsParamsMethodApplicable (EmitContext ec, ArrayList arguments,
- MethodBase candidate, bool do_varargs)
+ int arg_count, MethodBase candidate,
+ bool do_varargs)
{
- int arg_count;
-
- if (arguments == null)
- arg_count = 0;
- else
- arg_count = arguments.Count;
-
ParameterData pd = GetParameterData (candidate);
int pd_count = pd.Count;
Argument a = (Argument) arguments [i];
- Parameter.Modifier a_mod = a.GetParameterModifier () &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ Parameter.Modifier a_mod = a.GetParameterModifier () &
+ (unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF)));
Parameter.Modifier p_mod = pd.ParameterModifier (i) &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ (unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF)));
if (a_mod == p_mod) {
return true;
}
+ static bool IsApplicable (EmitContext ec, MethodGroupExpr me,
+ ArrayList arguments, int arg_count,
+ ref MethodBase candidate)
+ {
+ return IsApplicable (ec, arguments, arg_count, candidate);
+ }
+
/// <summary>
/// Determines if the candidate method is applicable (section 14.4.2.1)
/// to the given set of arguments
/// </summary>
- static bool IsApplicable (EmitContext ec, ArrayList arguments, MethodBase candidate)
+ static bool IsApplicable (EmitContext ec, ArrayList arguments, int arg_count,
+ MethodBase candidate)
{
- int arg_count;
-
- if (arguments == null)
- arg_count = 0;
- else
- arg_count = arguments.Count;
-
-
ParameterData pd = GetParameterData (candidate);
if (arg_count != pd.Count)
Argument a = (Argument) arguments [i];
Parameter.Modifier a_mod = a.GetParameterModifier () &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF));
Parameter.Modifier p_mod = pd.ParameterModifier (i) &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF));
if (a_mod == p_mod ||
return true;
}
+
+ static private bool IsAncestralType (Type first_type, Type second_type)
+ {
+ return first_type != second_type &&
+ (second_type.IsSubclassOf (first_type) ||
+ TypeManager.ImplementsInterface (second_type, first_type));
+ }
/// <summary>
/// Find the Applicable Function Members (7.4.2.1)
///
/// </summary>
public static MethodBase OverloadResolve (EmitContext ec, MethodGroupExpr me,
- ArrayList Arguments, Location loc)
+ ArrayList Arguments, bool may_fail,
+ Location loc)
{
MethodBase method = null;
+ bool method_params = false;
Type applicable_type = null;
- int argument_count;
+ int arg_count = 0;
ArrayList candidates = new ArrayList ();
//
//
Hashtable candidate_to_form = null;
+ if (Arguments != null)
+ arg_count = Arguments.Count;
- //
- // First we construct the set of applicable methods
- //
- // We start at the top of the type hierarchy and
- // go down to find applicable methods
- //
- applicable_type = me.DeclaringType;
-
- if (me.Name == "Invoke" && TypeManager.IsDelegateType (applicable_type)) {
+ if ((me.Name == "Invoke") &&
+ TypeManager.IsDelegateType (me.DeclaringType)) {
Error_InvokeOnDelegate (loc);
return null;
}
- bool found_applicable = false;
+ MethodBase[] methods = me.Methods;
- foreach (MethodBase candidate in me.Methods){
- Type decl_type = candidate.DeclaringType;
+ //
+ // First we construct the set of applicable methods
+ //
+ bool is_sorted = true;
+ for (int i = 0; i < methods.Length; i++){
+ Type decl_type = methods [i].DeclaringType;
//
// If we have already found an applicable method
// we eliminate all base types (Section 14.5.5.1)
//
- if (decl_type != applicable_type &&
- (applicable_type.IsSubclassOf (decl_type) ||
- TypeManager.ImplementsInterface (applicable_type, decl_type)) &&
- found_applicable)
- continue;
-
+ if ((applicable_type != null) &&
+ IsAncestralType (decl_type, applicable_type))
+ continue;
+ //
// Check if candidate is applicable (section 14.4.2.1)
- if (IsApplicable (ec, Arguments, candidate)) {
- // Candidate is applicable in normal form
- candidates.Add (candidate);
- applicable_type = candidate.DeclaringType;
- found_applicable = true;
- } else if (IsParamsMethodApplicable (ec, Arguments, candidate, false)) {
+ // Is candidate applicable in normal form?
+ //
+ bool is_applicable = IsApplicable (
+ ec, me, Arguments, arg_count, ref methods [i]);
+
+ if (!is_applicable &&
+ (IsParamsMethodApplicable (
+ ec, me, Arguments, arg_count, ref methods [i]))) {
+ MethodBase candidate = methods [i];
if (candidate_to_form == null)
candidate_to_form = new PtrHashtable ();
-
- // Candidate is applicable in expanded form
- candidates.Add (candidate);
- applicable_type = candidate.DeclaringType;
- found_applicable = true;
candidate_to_form [candidate] = candidate;
- } else if (IsParamsMethodApplicable (ec, Arguments, candidate, true)) {
- if (candidate_to_form == null)
- candidate_to_form = new PtrHashtable ();
-
// Candidate is applicable in expanded form
- candidates.Add (candidate);
- applicable_type = candidate.DeclaringType;
- found_applicable = true;
- candidate_to_form [candidate] = candidate;
+ is_applicable = true;
}
- }
-
- //
- // Now we actually find the best method
- //
- int candidate_top = candidates.Count;
- for (int ix = 0; ix < candidate_top; ix++){
- MethodBase candidate = (MethodBase) candidates [ix];
+ if (!is_applicable)
+ continue;
- bool cand_params = candidate_to_form != null && candidate_to_form.Contains (candidate);
- bool method_params = false;
+ candidates.Add (methods [i]);
- if (method != null)
- method_params = candidate_to_form != null && candidate_to_form.Contains (method);
-
- int x = BetterFunction (ec, Arguments,
- candidate, cand_params,
- method, method_params,
- loc);
-
- if (x == 0)
- continue;
-
- method = candidate;
- }
+ if (applicable_type == null)
+ applicable_type = decl_type;
+ else if (applicable_type != decl_type) {
+ is_sorted = false;
+ if (IsAncestralType (applicable_type, decl_type))
+ applicable_type = decl_type;
+ }
+ }
- if (Arguments == null)
- argument_count = 0;
- else
- argument_count = Arguments.Count;
-
+ int candidate_top = candidates.Count;
- if (method == null) {
+ if (candidate_top == 0) {
//
// Okay so we have failed to find anything so we
// return by providing info about the closest match
//
- for (int i = 0; i < me.Methods.Length; ++i) {
-
- MethodBase c = (MethodBase) me.Methods [i];
+ for (int i = 0; i < methods.Length; ++i) {
+ MethodBase c = (MethodBase) methods [i];
ParameterData pd = GetParameterData (c);
- if (pd.Count != argument_count)
+ if (pd.Count != arg_count)
continue;
- VerifyArgumentsCompat (ec, Arguments, argument_count, c, false,
- null, loc);
- break;
+ VerifyArgumentsCompat (ec, Arguments, arg_count,
+ c, false, null, may_fail, loc);
+ break;
}
- if (!Location.IsNull (loc)) {
+ if (!may_fail) {
string report_name = me.Name;
if (report_name == ".ctor")
report_name = me.DeclaringType.ToString ();
- Error_WrongNumArguments (loc, report_name, argument_count);
+ Error_WrongNumArguments (
+ loc, report_name, arg_count);
+ return null;
}
return null;
}
+ if (!is_sorted) {
+ //
+ // At this point, applicable_type is _one_ of the most derived types
+ // in the set of types containing the methods in this MethodGroup.
+ // Filter the candidates so that they only contain methods from the
+ // most derived types.
+ //
+
+ int finalized = 0; // Number of finalized candidates
+
+ do {
+ // Invariant: applicable_type is a most derived type
+
+ // We'll try to complete Section 14.5.5.1 for 'applicable_type' by
+ // eliminating all it's base types. At the same time, we'll also move
+ // every unrelated type to the end of the array, and pick the next
+ // 'applicable_type'.
+
+ Type next_applicable_type = null;
+ int j = finalized; // where to put the next finalized candidate
+ int k = finalized; // where to put the next undiscarded candidate
+ for (int i = finalized; i < candidate_top; ++i) {
+ Type decl_type = ((MethodBase) candidates[i]).DeclaringType;
+
+ if (decl_type == applicable_type) {
+ candidates[k++] = candidates[j];
+ candidates[j++] = candidates[i];
+ continue;
+ }
+
+ if (IsAncestralType (decl_type, applicable_type))
+ continue;
+
+ if (next_applicable_type != null &&
+ IsAncestralType (decl_type, next_applicable_type))
+ continue;
+
+ candidates[k++] = candidates[i];
+
+ if (next_applicable_type == null ||
+ IsAncestralType (next_applicable_type, decl_type))
+ next_applicable_type = decl_type;
+ }
+
+ applicable_type = next_applicable_type;
+ finalized = j;
+ candidate_top = k;
+ } while (applicable_type != null);
+ }
+
+ //
+ // Now we actually find the best method
+ //
+
+ method = (MethodBase) candidates[0];
+ method_params = candidate_to_form != null && candidate_to_form.Contains (method);
+ for (int ix = 1; ix < candidate_top; ix++){
+ MethodBase candidate = (MethodBase) candidates [ix];
+ bool cand_params = candidate_to_form != null && candidate_to_form.Contains (candidate);
+
+ if (BetterFunction (ec, Arguments, arg_count,
+ candidate, cand_params,
+ method, method_params, loc)) {
+ method = candidate;
+ method_params = cand_params;
+ }
+ }
+
//
// Now check that there are no ambiguities i.e the selected method
// should be better than all the others
//
- bool best_params = candidate_to_form != null && candidate_to_form.Contains (method);
-
+ bool ambiguous = false;
for (int ix = 0; ix < candidate_top; ix++){
MethodBase candidate = (MethodBase) candidates [ix];
if (candidate == method)
continue;
-
- //
- // If a normal method is applicable in
- // the sense that it has the same
- // number of arguments, then the
- // expanded params method is never
- // applicable so we debar the params
- // method.
- //
- // if ((IsParamsMethodApplicable (ec, Arguments, candidate) &&
-// IsApplicable (ec, Arguments, method)))
-// continue;
-
+
bool cand_params = candidate_to_form != null && candidate_to_form.Contains (candidate);
- int x = BetterFunction (ec, Arguments,
- method, best_params,
- candidate, cand_params,
- loc);
-
- if (x != 1) {
- Report.Error (
- 121, loc,
- "Ambiguous call when selecting function due to implicit casts");
- return null;
- }
+ if (!BetterFunction (ec, Arguments, arg_count,
+ method, method_params,
+ candidate, cand_params,
+ loc)) {
+ Report.SymbolRelatedToPreviousError (candidate);
+ ambiguous = true;
+ }
}
+ if (ambiguous) {
+ Report.SymbolRelatedToPreviousError (method);
+ Report.Error (121, loc, "Ambiguous call when selecting function due to implicit casts");
+ return null;
+ }
+
+
//
// And now check if the arguments are all
// compatible, perform conversions if
// necessary etc. and return if everything is
// all right
//
- if (!VerifyArgumentsCompat (ec, Arguments, argument_count, method,
- best_params, null, loc))
+ if (!VerifyArgumentsCompat (ec, Arguments, arg_count, method,
+ method_params, null, may_fail, loc))
return null;
return method;
}
public static bool VerifyArgumentsCompat (EmitContext ec, ArrayList Arguments,
- int argument_count,
- MethodBase method,
+ int arg_count, MethodBase method,
bool chose_params_expanded,
- Type delegate_type,
+ Type delegate_type, bool may_fail,
Location loc)
{
ParameterData pd = GetParameterData (method);
int pd_count = pd.Count;
- for (int j = 0; j < argument_count; j++) {
+ for (int j = 0; j < arg_count; j++) {
Argument a = (Argument) Arguments [j];
Expression a_expr = a.Expr;
Type parameter_type = pd.ParameterType (j);
if (pm == Parameter.Modifier.PARAMS){
if ((pm & ~Parameter.Modifier.PARAMS) != a.GetParameterModifier ()) {
- if (!Location.IsNull (loc))
+ if (!may_fail)
Error_InvalidArguments (
loc, j, method, delegate_type,
Argument.FullDesc (a), pd.ParameterDesc (j));
// Check modifiers
//
if (pd.ParameterModifier (j) != a.GetParameterModifier ()){
- if (!Location.IsNull (loc))
+ if (!may_fail)
Error_InvalidArguments (
loc, j, method, delegate_type,
Argument.FullDesc (a), pd.ParameterDesc (j));
//
// Check Type
//
- if (a.Type != parameter_type){
+ if (!a.Type.Equals (parameter_type)){
Expression conv;
conv = Convert.ImplicitConversion (ec, a_expr, parameter_type, loc);
if (conv == null) {
- if (!Location.IsNull (loc))
+ if (!may_fail)
Error_InvalidArguments (
loc, j, method, delegate_type,
Argument.FullDesc (a), pd.ParameterDesc (j));
a.Expr = conv;
}
+ if (parameter_type.IsPointer){
+ if (!ec.InUnsafe){
+ UnsafeError (loc);
+ return false;
+ }
+ }
+
Parameter.Modifier a_mod = a.GetParameterModifier () &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF));
Parameter.Modifier p_mod = pd.ParameterModifier (j) &
- ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
+ unchecked (~(Parameter.Modifier.OUT | Parameter.Modifier.REF));
if (a_mod != p_mod &&
pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS) {
- if (!Location.IsNull (loc)) {
+ if (!may_fail) {
Report.Error (1502, loc,
"The best overloaded match for method '" + FullMethodDesc (method)+
"' has some invalid arguments");
// First, resolve the expression that is used to
// trigger the invocation
//
- if (expr is BaseAccess)
- is_base = true;
-
expr = expr.Resolve (ec, ResolveFlags.VariableOrValue | ResolveFlags.MethodGroup);
if (expr == null)
return null;
}
if (!(expr is MethodGroupExpr)){
- expr.Error_UnexpectedKind (ResolveFlags.MethodGroup);
+ expr.Error_UnexpectedKind (ResolveFlags.MethodGroup, loc);
return null;
}
}
MethodGroupExpr mg = (MethodGroupExpr) expr;
- method = OverloadResolve (ec, mg, Arguments, loc);
+ method = OverloadResolve (ec, mg, Arguments, false, loc);
- if (method == null){
- Error (-6,
- "Could not find any applicable function for this argument list");
+ if (method == null)
return null;
- }
-
+
MethodInfo mi = method as MethodInfo;
if (mi != null) {
type = TypeManager.TypeToCoreType (mi.ReturnType);
//
// Only base will allow this invocation to happen.
//
- if (is_base && method.IsAbstract){
+ if (mg.IsBase && method.IsAbstract){
Report.Error (205, loc, "Cannot call an abstract base member: " +
FullMethodDesc (method));
return null;
}
- if ((method.Attributes & MethodAttributes.SpecialName) != 0){
- if (TypeManager.IsSpecialMethod (method))
- Report.Error (571, loc, method.Name + ": can not call operator or accessor");
+ if (method.Name == "Finalize" && Arguments == null) {
+ if (mg.IsBase)
+ Report.Error (250, loc, "Do not directly call your base class Finalize method. It is called automatically from your destructor");
+ else
+ Report.Error (245, loc, "Destructors and object.Finalize cannot be called directly. Consider calling IDisposable.Dispose if available");
+ return null;
+ }
+
+ if ((method.Attributes & MethodAttributes.SpecialName) != 0) {
+ if (TypeManager.LookupDeclSpace (method.DeclaringType) != null || TypeManager.IsSpecialMethod (method)) {
+ Report.Error (571, loc, TypeManager.CSharpSignature (method) + ": can not call operator or accessor");
+ return null;
+ }
}
+ if (mg.InstanceExpression != null)
+ mg.InstanceExpression.CheckMarshallByRefAccess (ec.ContainerType);
+
eclass = ExprClass.Value;
return this;
}
method = TypeManager.void_array_copyto_array_int;
}
- //
- // This checks ObsoleteAttribute on the method and on the declaring type
- //
- ObsoleteAttribute oa = AttributeTester.GetMethodObsoleteAttribute (method);
- if (oa != null)
- AttributeTester.Report_ObsoleteMessage (oa, TypeManager.CSharpSignature (method), loc);
+ if (ec.TestObsoleteMethodUsage) {
+ //
+ // This checks ObsoleteAttribute on the method and on the declaring type
+ //
+ ObsoleteAttribute oa = AttributeTester.GetMethodObsoleteAttribute (method);
+ if (oa != null)
+ AttributeTester.Report_ObsoleteMessage (oa, TypeManager.CSharpSignature (method), loc);
- oa = AttributeTester.GetObsoleteAttribute (method.DeclaringType);
- if (oa != null) {
- AttributeTester.Report_ObsoleteMessage (oa, method.DeclaringType.FullName, loc);
+ oa = AttributeTester.GetObsoleteAttribute (method.DeclaringType);
+ if (oa != null) {
+ AttributeTester.Report_ObsoleteMessage (oa, method.DeclaringType.FullName, loc);
+ }
}
if (IsMethodExcluded (method, ec))
{
MethodGroupExpr mg = (MethodGroupExpr) this.expr;
- EmitCall (ec, is_base, method.IsStatic, mg.InstanceExpression, method, Arguments, loc);
+ EmitCall (ec, mg.IsBase, method.IsStatic, mg.InstanceExpression, method, Arguments, loc);
}
public override void EmitStatement (EmitContext ec)
//
// First try to resolve it as a cast.
//
- type = ec.DeclSpace.ResolveType (expr, true, loc);
- if (type != null) {
- Cast cast = new Cast (new TypeExpression (type, loc), argument, loc);
+ TypeExpr te = expr.ResolveAsTypeTerminal (ec, true);
+ if (te != null) {
+ Cast cast = new Cast (te, argument, loc);
return cast.Resolve (ec);
}
//
// First try to resolve it as a cast.
//
- type = ec.DeclSpace.ResolveType (expr, true, loc);
- if (type != null) {
+ TypeExpr te = expr.ResolveAsTypeTerminal (ec, true);
+ if (te != null) {
error201 ();
return null;
}
value_target = value;
value_target_set = true;
if (!(value_target is IMemoryLocation)){
- Error_UnexpectedKind ("variable");
+ Error_UnexpectedKind ("variable", loc);
return false;
}
return true;
return this;
}
- type = ec.DeclSpace.ResolveType (RequestedType, false, loc);
-
- if (type == null)
+ TypeExpr texpr = RequestedType.ResolveAsTypeTerminal (ec, false);
+ if (texpr == null)
return null;
+
+ type = texpr.ResolveType (ec);
CheckObsoleteAttribute (type);
if (IsDelegate){
RequestedType = (new NewDelegate (type, Arguments, loc)).Resolve (ec);
if (RequestedType != null)
- if (!(RequestedType is NewDelegate))
+ if (!(RequestedType is DelegateCreation))
throw new Exception ("NewDelegate.Resolve returned a non NewDelegate: " + RequestedType.GetType ());
return RequestedType;
}
+ if (type.IsAbstract && type.IsSealed) {
+ Report.Error (712, loc, "Cannot create an instance of the static class '{0}'", TypeManager.CSharpName (type));
+ return null;
+ }
+
if (type.IsInterface || type.IsAbstract){
Error (144, "It is not possible to create instances of interfaces or abstract classes");
return null;
if (! (ml is MethodGroupExpr)){
if (!is_struct){
- ml.Error_UnexpectedKind ("method group");
+ ml.Error_UnexpectedKind ("method group", loc);
return null;
}
}
}
}
- method = Invocation.OverloadResolve (ec, (MethodGroupExpr) ml, Arguments, loc);
+ method = Invocation.OverloadResolve (
+ ec, (MethodGroupExpr) ml, Arguments, true, loc);
}
- if (method == null) {
+ if (method == null) {
+ if (almostMatchedMembers.Count != 0) {
+ MemberLookupFailed (ec, type, type, ".ctor", null, loc);
+ return null;
+ }
+
if (!is_struct || Arguments.Count > 0) {
Error (1501, String.Format (
"New invocation: Can not find a constructor in `{0}' for this argument list",
Expression tmp = (Expression) o;
tmp = tmp.Resolve (ec);
if (tmp == null)
- continue;
+ return false;
// Console.WriteLine ("I got: " + tmp);
// Handle initialization from vars, fields etc.
}
}
- void Error_NegativeArrayIndex ()
- {
- Error (284, "Can not create array with a negative size");
- }
-
//
// Converts `source' to an int, uint, long or ulong.
//
if (target is Constant){
if (target is IntConstant){
if (((IntConstant) target).Value < 0){
- Error_NegativeArrayIndex ();
+ Expression.Error_NegativeArrayIndex (loc);
return null;
}
}
if (target is LongConstant){
if (((LongConstant) target).Value < 0){
- Error_NegativeArrayIndex ();
+ Expression.Error_NegativeArrayIndex (loc);
return null;
}
}
//
// Lookup the type
//
- Expression array_type_expr;
+ TypeExpr array_type_expr;
array_type_expr = new ComposedCast (requested_base_type, array_qualifier.ToString (), loc);
- type = ec.DeclSpace.ResolveType (array_type_expr, false, loc);
-
- if (type == null)
+ array_type_expr = array_type_expr.ResolveAsTypeTerminal (ec, false);
+ if (array_type_expr == null)
return false;
- underlying_type = type;
- if (underlying_type.IsArray)
- underlying_type = TypeManager.GetElementType (underlying_type);
+ type = array_type_expr.ResolveType (ec);
+
+ if (!type.IsArray) {
+ Error (622, "Can only use array initializer expressions to assign to array types. Try using a new expression instead.");
+ return false;
+ }
+ underlying_type = TypeManager.GetElementType (type);
dimensions = type.GetArrayRank ();
return true;
array_element_type = TypeManager.GetElementType (type);
+ if (array_element_type.IsAbstract && array_element_type.IsSealed) {
+ Report.Error (719, loc, "'{0}': array elements cannot be of static type", TypeManager.CSharpName (array_element_type));
+ return null;
+ }
+
if (arg_count == 1) {
is_one_dimensional = true;
eclass = ExprClass.Value;
AllBindingFlags, loc);
if (!(ml is MethodGroupExpr)) {
- ml.Error_UnexpectedKind ("method group");
+ ml.Error_UnexpectedKind ("method group", loc);
return null;
}
return null;
}
- new_method = Invocation.OverloadResolve (ec, (MethodGroupExpr) ml, arguments, loc);
+ new_method = Invocation.OverloadResolve (
+ ec, (MethodGroupExpr) ml, arguments, false, loc);
if (new_method == null) {
Error (-6, "New invocation: Can not find a constructor for " +
if (e is NullLiteral)
v = null;
else {
- if (!Attribute.GetAttributeArgumentExpression (e, Location, out v))
+ if (!Attribute.GetAttributeArgumentExpression (e, Location, array_element_type, out v))
return null;
}
ret [i++] = v;
}
return ret;
}
-
- public Expression TurnIntoConstant ()
- {
- //
- // Should use something like the above attribute thing.
- // It should return a subclass of Constant that just returns
- // the computed value of the array
- //
- throw new Exception ("Does not support yet Turning array into a Constant");
- }
}
/// <summary>
/// Implements the typeof operator
/// </summary>
public class TypeOf : Expression {
- public readonly Expression QueriedType;
+ public Expression QueriedType;
protected Type typearg;
public TypeOf (Expression queried_type, Location l)
public override Expression DoResolve (EmitContext ec)
{
- typearg = ec.DeclSpace.ResolveType (QueriedType, false, loc);
-
- if (typearg == null)
+ TypeExpr texpr = QueriedType.ResolveAsTypeTerminal (ec, false);
+ if (texpr == null)
return null;
+ typearg = texpr.ResolveType (ec);
+
if (typearg == TypeManager.void_type) {
Error (673, "System.Void cannot be used from C# - " +
"use typeof (void) to get the void type object");
return null;
}
+ if (typearg.IsPointer && !ec.InUnsafe){
+ UnsafeError (loc);
+ return null;
+ }
CheckObsoleteAttribute (typearg);
type = TypeManager.type_type;
/// Implements the sizeof expression
/// </summary>
public class SizeOf : Expression {
- public readonly Expression QueriedType;
+ public Expression QueriedType;
Type type_queried;
public SizeOf (Expression queried_type, Location l)
if (!ec.InUnsafe) {
Report.Error (
233, loc, "Sizeof may only be used in an unsafe context " +
- "(consider using System.Runtime.InteropServices.Marshal.Sizeof");
+ "(consider using System.Runtime.InteropServices.Marshal.SizeOf");
return null;
}
-
- type_queried = ec.DeclSpace.ResolveType (QueriedType, false, loc);
- if (type_queried == null)
+
+ TypeExpr texpr = QueriedType.ResolveAsTypeTerminal (ec, false);
+ if (texpr == null)
return null;
+ type_queried = texpr.ResolveType (ec);
+
CheckObsoleteAttribute (type_queried);
if (!TypeManager.IsUnmanagedType (type_queried)){
if (sn == null || left == null || left.Type.Name != sn.Name)
return false;
- return RootContext.LookupType (ec.DeclSpace, sn.Name, true, loc) != null;
+ return ec.DeclSpace.LookupType (sn.Name, true, loc) != null;
}
+ // TODO: possible optimalization
+ // Cache resolved constant result in FieldBuilder <-> expresion map
public static Expression ResolveMemberAccess (EmitContext ec, Expression member_lookup,
Expression left, Location loc,
Expression left_original)
FieldInfo fi = fe.FieldInfo;
Type decl_type = fi.DeclaringType;
- if (fi is FieldBuilder) {
+ bool is_emitted = fi is FieldBuilder;
+ Type t = fi.FieldType;
+
+ if (is_emitted) {
Const c = TypeManager.LookupConstant ((FieldBuilder) fi);
if (c != null) {
object real_value = ((Constant) c.Expr).GetValue ();
- return Constantify (real_value, fi.FieldType);
+ Expression exp = Constantify (real_value, t);
+
+ if (left_is_explicit && !left_is_type && !IdenticalNameAndTypeName (ec, left_original, left, loc)) {
+ Report.SymbolRelatedToPreviousError (c);
+ error176 (loc, c.GetSignatureForError ());
+ return null;
+ }
+
+ return exp;
}
}
+ // IsInitOnly is because of MS compatibility, I don't know why but they emit decimal constant as InitOnly
+ if (fi.IsInitOnly && !is_emitted && t == TypeManager.decimal_type) {
+ object[] attrs = fi.GetCustomAttributes (TypeManager.decimal_constant_attribute_type, false);
+ if (attrs.Length == 1)
+ return new DecimalConstant (((System.Runtime.CompilerServices.DecimalConstantAttribute) attrs [0]).Value);
+ }
+
if (fi.IsLiteral) {
- Type t = fi.FieldType;
-
object o;
- if (fi is FieldBuilder)
+ if (is_emitted)
o = TypeManager.GetValue ((FieldBuilder) fi);
else
o = fi.GetValue (fi);
return exp;
}
- if (fi.FieldType.IsPointer && !ec.InUnsafe){
+ if (t.IsPointer && !ec.InUnsafe){
UnsafeError (loc);
return null;
}
if (expr == null)
return null;
- if (expr is SimpleName){
- SimpleName child_expr = (SimpleName) expr;
-
- Expression new_expr = new SimpleName (child_expr.Name, Identifier, loc);
-
- return new_expr.Resolve (ec, flags);
+ if (expr is Namespace) {
+ Namespace ns = (Namespace) expr;
+ FullNamedExpression retval = ns.Lookup (ec.DeclSpace, Identifier, loc);
+ if (retval == null)
+ Report.Error (234, loc, "The type or namespace name `{0}' could not be found in namespace `{1}'", Identifier, ns.FullName);
+ return retval;
}
//
Type expr_type = expr.Type;
if (expr is TypeExpr){
if (!ec.DeclSpace.CheckAccessLevel (expr_type)){
- Report.Error_T (122, loc, expr_type);
+ Report.Error (122, loc, "'{0}' is inaccessible due to its protection level", expr_type);
return null;
}
object value = en.LookupEnumValue (ec, Identifier, loc);
if (value != null){
- ObsoleteAttribute oa = en.GetObsoleteAttribute (ec, Identifier);
+ MemberCore mc = en.GetDefinition (Identifier);
+ ObsoleteAttribute oa = mc.GetObsoleteAttribute (en);
+ if (oa != null) {
+ AttributeTester.Report_ObsoleteMessage (oa, mc.GetSignatureForError (), Location);
+ }
+ oa = en.GetObsoleteAttribute (en);
if (oa != null) {
AttributeTester.Report_ObsoleteMessage (oa, en.GetSignatureForError (), Location);
}
return null;
if (member_lookup is TypeExpr) {
- if (!(expr is TypeExpr) && !(expr is SimpleName)) {
+ if (!(expr is TypeExpr) &&
+ !IdenticalNameAndTypeName (ec, original, expr, loc)) {
Error (572, "Can't reference type `" + Identifier + "' through an expression; try `" +
member_lookup.Type + "' instead");
return null;
public override Expression DoResolve (EmitContext ec)
{
- return DoResolve (ec, null, ResolveFlags.VariableOrValue |
- ResolveFlags.SimpleName | ResolveFlags.Type);
+ return DoResolve (ec, null, ResolveFlags.VariableOrValue | ResolveFlags.Type);
}
public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
- return DoResolve (ec, right_side, ResolveFlags.VariableOrValue |
- ResolveFlags.SimpleName | ResolveFlags.Type);
+ return DoResolve (ec, right_side, ResolveFlags.VariableOrValue | ResolveFlags.Type);
}
- public override Expression ResolveAsTypeStep (EmitContext ec)
+ public override FullNamedExpression ResolveAsTypeStep (EmitContext ec)
{
- string fname = null;
- MemberAccess full_expr = this;
- while (full_expr != null) {
- if (fname != null)
- fname = String.Concat (full_expr.Identifier, ".", fname);
- else
- fname = full_expr.Identifier;
-
- if (full_expr.Expr is SimpleName) {
- string full_name = String.Concat (((SimpleName) full_expr.Expr).Name, ".", fname);
- Type fully_qualified = ec.DeclSpace.FindType (loc, full_name);
- if (fully_qualified != null)
- return new TypeExpression (fully_qualified, loc);
- }
-
- full_expr = full_expr.Expr as MemberAccess;
- }
+ return ResolveNamespaceOrType (ec, false);
+ }
- Expression new_expr = expr.ResolveAsTypeStep (ec);
+ public FullNamedExpression ResolveNamespaceOrType (EmitContext ec, bool silent)
+ {
+ FullNamedExpression new_expr = expr.ResolveAsTypeStep (ec);
if (new_expr == null)
return null;
- if (new_expr is SimpleName){
- SimpleName child_expr = (SimpleName) new_expr;
-
- new_expr = new SimpleName (child_expr.Name, Identifier, loc);
-
- return new_expr.ResolveAsTypeStep (ec);
+ if (new_expr is Namespace) {
+ Namespace ns = (Namespace) new_expr;
+ FullNamedExpression retval = ns.Lookup (ec.DeclSpace, Identifier, loc);
+ if (!silent && retval == null)
+ Report.Error (234, loc, "The type or namespace name `{0}' could not be found in namespace `{1}'", Identifier, ns.FullName);
+ return retval;
}
Type expr_type = new_expr.Type;
return null;
}
- Expression member_lookup;
- member_lookup = MemberLookupFinal (ec, expr_type, expr_type, Identifier, loc);
- if (member_lookup == null)
+ Expression member_lookup = MemberLookupFinal (ec, expr_type, expr_type, Identifier, loc);
+ if (!silent && member_lookup == null) {
+ Report.Error (234, loc, "The type name `{0}' could not be found in type `{1}'",
+ Identifier, new_expr.FullName);
return null;
+ }
- if (member_lookup is TypeExpr){
- member_lookup.Resolve (ec, ResolveFlags.Type);
- return member_lookup;
+ if (!(member_lookup is TypeExpr)) {
+ Report.Error (118, loc, "'{0}.{1}' denotes a '{2}', where a type was expected",
+ new_expr.FullName, Identifier, member_lookup.ExprClassName ());
+ return null;
}
- return null;
+ member_lookup = member_lookup.Resolve (ec, ResolveFlags.Type);
+ return (member_lookup as TypeExpr);
}
public override void Emit (EmitContext ec)
return true;
}
- Expression MakePointerAccess ()
+ Expression MakePointerAccess (EmitContext ec)
{
Type t = Expr.Type;
}
Expression p;
- p = new PointerArithmetic (true, Expr, ((Argument)Arguments [0]).Expr, t, loc);
- return new Indirection (p, loc);
+ p = new PointerArithmetic (true, Expr, ((Argument)Arguments [0]).Expr, t, loc).Resolve (ec);
+ if (p == null)
+ return null;
+ return new Indirection (p, loc).Resolve (ec);
}
public override Expression DoResolve (EmitContext ec)
if (t.IsArray)
return (new ArrayAccess (this, loc)).Resolve (ec);
else if (t.IsPointer)
- return MakePointerAccess ();
+ return MakePointerAccess (ec);
else
return (new IndexerAccess (this, loc)).Resolve (ec);
}
if (t.IsArray)
return (new ArrayAccess (this, loc)).ResolveLValue (ec, right_side);
else if (t.IsPointer)
- return MakePointerAccess ();
+ return MakePointerAccess (ec);
else
return (new IndexerAccess (this, loc)).ResolveLValue (ec, right_side);
}
if (argtype == TypeManager.int32_type ||
argtype == TypeManager.uint32_type ||
argtype == TypeManager.int64_type ||
- argtype == TypeManager.uint64_type)
+ argtype == TypeManager.uint64_type) {
+ Constant c = a.Expr as Constant;
+ if (c != null && c.IsNegative) {
+ Report.Warning (251, 2, a.Expr.Location, "Indexing an array with a negative index (array indices always start at zero)");
+ }
continue;
+ }
//
// Mhm. This is strage, because the Argument.Type is not the same as
if (!lookup_type.IsInterface)
return ix;
- TypeExpr [] ifaces = TypeManager.GetInterfaces (lookup_type);
+ Type [] ifaces = TypeManager.GetInterfaces (lookup_type);
if (ifaces != null) {
- foreach (TypeExpr iface in ifaces) {
- Type itype = iface.Type;
+ foreach (Type itype in ifaces) {
MemberInfo [] mi = GetIndexersForTypeOrInterface (caller_type, itype);
if (mi != null){
if (ix == null)
if (AllGetters.Count > 0) {
found_any_getters = true;
get = (MethodInfo) Invocation.OverloadResolve (
- ec, new MethodGroupExpr (AllGetters, loc), arguments, loc);
+ ec, new MethodGroupExpr (AllGetters, loc),
+ arguments, false, loc);
}
if (!found_any) {
UnsafeError (loc);
return null;
}
+
+ instance_expr.CheckMarshallByRefAccess (ec.ContainerType);
eclass = ExprClass.IndexerAccess;
return this;
set_arguments.Add (new Argument (right_side, Argument.AType.Expression));
set = (MethodInfo) Invocation.OverloadResolve (
ec, new MethodGroupExpr (AllSetters, loc),
- set_arguments, loc);
+ set_arguments, false, loc);
}
if (!found_any) {
}
}
+ instance_expr.CheckMarshallByRefAccess (ec.ContainerType);
+
eclass = ExprClass.IndexerAccess;
return this;
}
pe.IsBase = true;
}
+
+ if (e is MethodGroupExpr)
+ ((MethodGroupExpr) e).IsBase = true;
return e;
}
/// is needed (the `New' class).
/// </summary>
public class EmptyExpression : Expression {
+ public static readonly EmptyExpression Null = new EmptyExpression ();
+
+ // TODO: should be protected
public EmptyExpression ()
{
type = TypeManager.object_type;
loc = l;
}
+ public Expression Source {
+ get {
+ return source;
+ }
+ }
+
public override Expression DoResolve (EmitContext ec)
{
//
public override TypeExpr DoResolveAsTypeStep (EmitContext ec)
{
- Type ltype = ec.DeclSpace.ResolveType (left, false, loc);
- if (ltype == null)
+ TypeExpr lexpr = left.ResolveAsTypeTerminal (ec, false);
+ if (lexpr == null)
return null;
+ Type ltype = lexpr.ResolveType (ec);
+
if ((ltype == TypeManager.void_type) && (dim != "*")) {
Report.Error (1547, Location,
"Keyword 'void' cannot be used in this context");
//
// For now, fall back to the full lookup in that case.
//
- type = RootContext.LookupType (
- ec.DeclSpace, cname, false, loc);
-
+ FullNamedExpression e = ec.DeclSpace.LookupType (cname, false, loc);
+ if (e is TypeExpr)
+ type = ((TypeExpr) e).ResolveType (ec);
if (type == null)
return null;
}
- if (!ec.ResolvingTypeTree){
- //
- // If the above flag is set, this is being invoked from the ResolveType function.
- // Upper layers take care of the type validity in this context.
- //
if (!ec.InUnsafe && type.IsPointer){
UnsafeError (loc);
return null;
}
+
+ if (type.IsArray && (type.GetElementType () == TypeManager.arg_iterator_type ||
+ type.GetElementType () == TypeManager.typed_reference_type)) {
+ Report.Error (611, loc, "Array elements cannot be of type '{0}'", TypeManager.CSharpName (type.GetElementType ()));
+ return null;
}
eclass = ExprClass.Type;
return left + dim;
}
}
+
+ public override string FullName {
+ get {
+ return type.FullName;
+ }
+ }
}
//
}
Constant c = count as Constant;
- // TODO: because we don't have property IsNegative
- if (c != null && c.ConvertToUInt () == null) {
- // "Cannot use a negative size with stackalloc"
- Report.Error_T (247, loc);
+ if (c != null && c.IsNegative) {
+ Report.Error (247, loc, "Cannot use a negative size with stackalloc");
return null;
}
return null;
}
- otype = ec.DeclSpace.ResolveType (t, false, loc);
-
- if (otype == null)
+ TypeExpr texpr = t.ResolveAsTypeTerminal (ec, false);
+ if (texpr == null)
return null;
+ otype = texpr.ResolveType (ec);
+
if (!TypeManager.VerifyUnManaged (otype, loc))
return null;