2 // expression.cs: Expression representation for the IL tree.
5 // Miguel de Icaza (miguel@ximian.com)
7 // (C) 2001, 2002, 2003 Ximian, Inc.
8 // (C) 2003, 2004 Novell, Inc.
12 namespace Mono.CSharp {
14 using System.Collections;
15 using System.Reflection;
16 using System.Reflection.Emit;
20 /// This is just a helper class, it is generated by Unary, UnaryMutator
21 /// when an overloaded method has been found. It just emits the code for a
24 public class StaticCallExpr : ExpressionStatement {
28 public StaticCallExpr (MethodInfo m, ArrayList a, Location l)
34 eclass = ExprClass.Value;
38 public override Expression DoResolve (EmitContext ec)
41 // We are born fully resolved
46 public override void Emit (EmitContext ec)
49 Invocation.EmitArguments (ec, mi, args);
51 ec.ig.Emit (OpCodes.Call, mi);
55 static public Expression MakeSimpleCall (EmitContext ec, MethodGroupExpr mg,
56 Expression e, Location loc)
61 args = new ArrayList (1);
62 Argument a = new Argument (e, Argument.AType.Expression);
64 // We need to resolve the arguments before sending them in !
65 if (!a.Resolve (ec, loc))
69 method = Invocation.OverloadResolve (
70 ec, (MethodGroupExpr) mg, args, false, loc);
75 return new StaticCallExpr ((MethodInfo) method, args, loc);
78 public override void EmitStatement (EmitContext ec)
81 if (TypeManager.TypeToCoreType (type) != TypeManager.void_type)
82 ec.ig.Emit (OpCodes.Pop);
86 public class ParenthesizedExpression : Expression
88 public Expression Expr;
90 public ParenthesizedExpression (Expression expr, Location loc)
96 public override Expression DoResolve (EmitContext ec)
98 Expr = Expr.Resolve (ec);
102 public override void Emit (EmitContext ec)
104 throw new Exception ("Should not happen");
109 /// Unary expressions.
113 /// Unary implements unary expressions. It derives from
114 /// ExpressionStatement becuase the pre/post increment/decrement
115 /// operators can be used in a statement context.
117 public class Unary : Expression {
118 public enum Operator : byte {
119 UnaryPlus, UnaryNegation, LogicalNot, OnesComplement,
120 Indirection, AddressOf, TOP
123 public Operator Oper;
124 public Expression Expr;
126 public Unary (Operator op, Expression expr, Location loc)
134 /// Returns a stringified representation of the Operator
136 static public string OperName (Operator oper)
139 case Operator.UnaryPlus:
141 case Operator.UnaryNegation:
143 case Operator.LogicalNot:
145 case Operator.OnesComplement:
147 case Operator.AddressOf:
149 case Operator.Indirection:
153 return oper.ToString ();
156 public static readonly string [] oper_names;
160 oper_names = new string [(int)Operator.TOP];
162 oper_names [(int) Operator.UnaryPlus] = "op_UnaryPlus";
163 oper_names [(int) Operator.UnaryNegation] = "op_UnaryNegation";
164 oper_names [(int) Operator.LogicalNot] = "op_LogicalNot";
165 oper_names [(int) Operator.OnesComplement] = "op_OnesComplement";
166 oper_names [(int) Operator.Indirection] = "op_Indirection";
167 oper_names [(int) Operator.AddressOf] = "op_AddressOf";
170 void Error23 (Type t)
173 23, "Operator " + OperName (Oper) +
174 " cannot be applied to operand of type `" +
175 TypeManager.CSharpName (t) + "'");
179 /// The result has been already resolved:
181 /// FIXME: a minus constant -128 sbyte cant be turned into a
184 static Expression TryReduceNegative (Constant expr)
188 if (expr is IntConstant)
189 e = new IntConstant (-((IntConstant) expr).Value);
190 else if (expr is UIntConstant){
191 uint value = ((UIntConstant) expr).Value;
193 if (value < 2147483649)
194 return new IntConstant (-(int)value);
196 e = new LongConstant (-value);
198 else if (expr is LongConstant)
199 e = new LongConstant (-((LongConstant) expr).Value);
200 else if (expr is ULongConstant){
201 ulong value = ((ULongConstant) expr).Value;
203 if (value < 9223372036854775809)
204 return new LongConstant(-(long)value);
206 else if (expr is FloatConstant)
207 e = new FloatConstant (-((FloatConstant) expr).Value);
208 else if (expr is DoubleConstant)
209 e = new DoubleConstant (-((DoubleConstant) expr).Value);
210 else if (expr is DecimalConstant)
211 e = new DecimalConstant (-((DecimalConstant) expr).Value);
212 else if (expr is ShortConstant)
213 e = new IntConstant (-((ShortConstant) expr).Value);
214 else if (expr is UShortConstant)
215 e = new IntConstant (-((UShortConstant) expr).Value);
220 // This routine will attempt to simplify the unary expression when the
221 // argument is a constant. The result is returned in `result' and the
222 // function returns true or false depending on whether a reduction
223 // was performed or not
225 bool Reduce (EmitContext ec, Constant e, out Expression result)
227 Type expr_type = e.Type;
230 case Operator.UnaryPlus:
234 case Operator.UnaryNegation:
235 result = TryReduceNegative (e);
238 case Operator.LogicalNot:
239 if (expr_type != TypeManager.bool_type) {
245 BoolConstant b = (BoolConstant) e;
246 result = new BoolConstant (!(b.Value));
249 case Operator.OnesComplement:
250 if (!((expr_type == TypeManager.int32_type) ||
251 (expr_type == TypeManager.uint32_type) ||
252 (expr_type == TypeManager.int64_type) ||
253 (expr_type == TypeManager.uint64_type) ||
254 (expr_type.IsSubclassOf (TypeManager.enum_type)))){
257 if (Convert.ImplicitConversionExists (ec, e, TypeManager.int32_type)){
258 result = new Cast (new TypeExpression (TypeManager.int32_type, loc), e, loc);
259 result = result.Resolve (ec);
260 } else if (Convert.ImplicitConversionExists (ec, e, TypeManager.uint32_type)){
261 result = new Cast (new TypeExpression (TypeManager.uint32_type, loc), e, loc);
262 result = result.Resolve (ec);
263 } else if (Convert.ImplicitConversionExists (ec, e, TypeManager.int64_type)){
264 result = new Cast (new TypeExpression (TypeManager.int64_type, loc), e, loc);
265 result = result.Resolve (ec);
266 } else if (Convert.ImplicitConversionExists (ec, e, TypeManager.uint64_type)){
267 result = new Cast (new TypeExpression (TypeManager.uint64_type, loc), e, loc);
268 result = result.Resolve (ec);
271 if (result == null || !(result is Constant)){
277 expr_type = result.Type;
278 e = (Constant) result;
281 if (e is EnumConstant){
282 EnumConstant enum_constant = (EnumConstant) e;
285 if (Reduce (ec, enum_constant.Child, out reduced)){
286 result = new EnumConstant ((Constant) reduced, enum_constant.Type);
294 if (expr_type == TypeManager.int32_type){
295 result = new IntConstant (~ ((IntConstant) e).Value);
296 } else if (expr_type == TypeManager.uint32_type){
297 result = new UIntConstant (~ ((UIntConstant) e).Value);
298 } else if (expr_type == TypeManager.int64_type){
299 result = new LongConstant (~ ((LongConstant) e).Value);
300 } else if (expr_type == TypeManager.uint64_type){
301 result = new ULongConstant (~ ((ULongConstant) e).Value);
309 case Operator.AddressOf:
313 case Operator.Indirection:
317 throw new Exception ("Can not constant fold: " + Oper.ToString());
320 Expression ResolveOperator (EmitContext ec)
322 Type expr_type = Expr.Type;
325 // Step 1: Perform Operator Overload location
330 op_name = oper_names [(int) Oper];
332 mg = MemberLookup (ec, expr_type, op_name, MemberTypes.Method, AllBindingFlags, loc);
335 Expression e = StaticCallExpr.MakeSimpleCall (
336 ec, (MethodGroupExpr) mg, Expr, loc);
346 // Only perform numeric promotions on:
349 if (expr_type == null)
353 // Step 2: Default operations on CLI native types.
356 // Attempt to use a constant folding operation.
357 if (Expr is Constant){
360 if (Reduce (ec, (Constant) Expr, out result))
365 case Operator.LogicalNot:
366 if (expr_type != TypeManager.bool_type) {
367 Expr = ResolveBoolean (ec, Expr, loc);
374 type = TypeManager.bool_type;
377 case Operator.OnesComplement:
378 if (!((expr_type == TypeManager.int32_type) ||
379 (expr_type == TypeManager.uint32_type) ||
380 (expr_type == TypeManager.int64_type) ||
381 (expr_type == TypeManager.uint64_type) ||
382 (expr_type.IsSubclassOf (TypeManager.enum_type)))){
385 e = Convert.ImplicitConversion (ec, Expr, TypeManager.int32_type, loc);
387 type = TypeManager.int32_type;
390 e = Convert.ImplicitConversion (ec, Expr, TypeManager.uint32_type, loc);
392 type = TypeManager.uint32_type;
395 e = Convert.ImplicitConversion (ec, Expr, TypeManager.int64_type, loc);
397 type = TypeManager.int64_type;
400 e = Convert.ImplicitConversion (ec, Expr, TypeManager.uint64_type, loc);
402 type = TypeManager.uint64_type;
411 case Operator.AddressOf:
412 if (Expr.eclass != ExprClass.Variable){
413 Error (211, "Cannot take the address of non-variables");
422 if (!TypeManager.VerifyUnManaged (Expr.Type, loc)){
426 IVariable variable = Expr as IVariable;
427 if (!ec.InFixedInitializer && ((variable == null) || !variable.VerifyFixed (false))) {
428 Error (212, "You can only take the address of an unfixed expression inside " +
429 "of a fixed statement initializer");
433 if (ec.InFixedInitializer && ((variable != null) && variable.VerifyFixed (false))) {
434 Error (213, "You can not fix an already fixed expression");
438 // According to the specs, a variable is considered definitely assigned if you take
440 if ((variable != null) && (variable.VariableInfo != null))
441 variable.VariableInfo.SetAssigned (ec);
443 type = TypeManager.GetPointerType (Expr.Type);
446 case Operator.Indirection:
452 if (!expr_type.IsPointer){
453 Error (193, "The * or -> operator can only be applied to pointers");
458 // We create an Indirection expression, because
459 // it can implement the IMemoryLocation.
461 return new Indirection (Expr, loc);
463 case Operator.UnaryPlus:
465 // A plus in front of something is just a no-op, so return the child.
469 case Operator.UnaryNegation:
471 // Deals with -literals
472 // int operator- (int x)
473 // long operator- (long x)
474 // float operator- (float f)
475 // double operator- (double d)
476 // decimal operator- (decimal d)
478 Expression expr = null;
481 // transform - - expr into expr
484 Unary unary = (Unary) Expr;
486 if (unary.Oper == Operator.UnaryNegation)
491 // perform numeric promotions to int,
495 // The following is inneficient, because we call
496 // ImplicitConversion too many times.
498 // It is also not clear if we should convert to Float
499 // or Double initially.
501 if (expr_type == TypeManager.uint32_type){
503 // FIXME: handle exception to this rule that
504 // permits the int value -2147483648 (-2^31) to
505 // bt wrote as a decimal interger literal
507 type = TypeManager.int64_type;
508 Expr = Convert.ImplicitConversion (ec, Expr, type, loc);
512 if (expr_type == TypeManager.uint64_type){
514 // FIXME: Handle exception of `long value'
515 // -92233720368547758087 (-2^63) to be wrote as
516 // decimal integer literal.
522 if (expr_type == TypeManager.float_type){
527 expr = Convert.ImplicitConversion (ec, Expr, TypeManager.int32_type, loc);
534 expr = Convert.ImplicitConversion (ec, Expr, TypeManager.int64_type, loc);
541 expr = Convert.ImplicitConversion (ec, Expr, TypeManager.double_type, loc);
552 Error (187, "No such operator '" + OperName (Oper) + "' defined for type '" +
553 TypeManager.CSharpName (expr_type) + "'");
557 public override Expression DoResolve (EmitContext ec)
559 if (Oper == Operator.AddressOf)
560 Expr = Expr.ResolveLValue (ec, new EmptyExpression ());
562 Expr = Expr.Resolve (ec);
567 eclass = ExprClass.Value;
568 return ResolveOperator (ec);
571 public override Expression DoResolveLValue (EmitContext ec, Expression right)
573 if (Oper == Operator.Indirection)
574 return base.DoResolveLValue (ec, right);
576 Error (131, "The left-hand side of an assignment must be a " +
577 "variable, property or indexer");
581 public override void Emit (EmitContext ec)
583 ILGenerator ig = ec.ig;
586 case Operator.UnaryPlus:
587 throw new Exception ("This should be caught by Resolve");
589 case Operator.UnaryNegation:
591 ig.Emit (OpCodes.Ldc_I4_0);
592 if (type == TypeManager.int64_type)
593 ig.Emit (OpCodes.Conv_U8);
595 ig.Emit (OpCodes.Sub_Ovf);
598 ig.Emit (OpCodes.Neg);
603 case Operator.LogicalNot:
605 ig.Emit (OpCodes.Ldc_I4_0);
606 ig.Emit (OpCodes.Ceq);
609 case Operator.OnesComplement:
611 ig.Emit (OpCodes.Not);
614 case Operator.AddressOf:
615 ((IMemoryLocation)Expr).AddressOf (ec, AddressOp.LoadStore);
619 throw new Exception ("This should not happen: Operator = "
624 public override void EmitBranchable (EmitContext ec, Label target, bool onTrue)
626 if (Oper == Operator.LogicalNot)
627 Expr.EmitBranchable (ec, target, !onTrue);
629 base.EmitBranchable (ec, target, onTrue);
632 public override string ToString ()
634 return "Unary (" + Oper + ", " + Expr + ")";
640 // Unary operators are turned into Indirection expressions
641 // after semantic analysis (this is so we can take the address
642 // of an indirection).
644 public class Indirection : Expression, IMemoryLocation, IAssignMethod {
646 LocalTemporary temporary;
649 public Indirection (Expression expr, Location l)
652 this.type = TypeManager.GetElementType (expr.Type);
653 eclass = ExprClass.Variable;
657 void LoadExprValue (EmitContext ec)
661 public override void Emit (EmitContext ec)
663 ILGenerator ig = ec.ig;
665 if (temporary != null){
666 if (have_temporary) {
670 ec.ig.Emit (OpCodes.Dup);
671 temporary.Store (ec);
672 have_temporary = true;
677 LoadFromPtr (ig, Type);
680 public void EmitAssign (EmitContext ec, Expression source)
682 if (temporary != null){
687 ec.ig.Emit (OpCodes.Dup);
688 temporary.Store (ec);
689 have_temporary = true;
695 StoreFromPtr (ec.ig, type);
698 public void AddressOf (EmitContext ec, AddressOp Mode)
700 if (temporary != null){
706 ec.ig.Emit (OpCodes.Dup);
707 temporary.Store (ec);
708 have_temporary = true;
713 public override Expression DoResolve (EmitContext ec)
716 // Born fully resolved
721 public new void CacheTemporaries (EmitContext ec)
723 temporary = new LocalTemporary (ec, expr.Type);
726 public override string ToString ()
728 return "*(" + expr + ")";
733 /// Unary Mutator expressions (pre and post ++ and --)
737 /// UnaryMutator implements ++ and -- expressions. It derives from
738 /// ExpressionStatement becuase the pre/post increment/decrement
739 /// operators can be used in a statement context.
741 /// FIXME: Idea, we could split this up in two classes, one simpler
742 /// for the common case, and one with the extra fields for more complex
743 /// classes (indexers require temporary access; overloaded require method)
746 public class UnaryMutator : ExpressionStatement {
748 public enum Mode : byte {
755 PreDecrement = IsDecrement,
756 PostIncrement = IsPost,
757 PostDecrement = IsPost | IsDecrement
762 LocalTemporary temp_storage;
765 // This is expensive for the simplest case.
769 public UnaryMutator (Mode m, Expression e, Location l)
776 static string OperName (Mode mode)
778 return (mode == Mode.PreIncrement || mode == Mode.PostIncrement) ?
782 void Error23 (Type t)
785 23, "Operator " + OperName (mode) +
786 " cannot be applied to operand of type `" +
787 TypeManager.CSharpName (t) + "'");
791 /// Returns whether an object of type `t' can be incremented
792 /// or decremented with add/sub (ie, basically whether we can
793 /// use pre-post incr-decr operations on it, but it is not a
794 /// System.Decimal, which we require operator overloading to catch)
796 static bool IsIncrementableNumber (Type t)
798 return (t == TypeManager.sbyte_type) ||
799 (t == TypeManager.byte_type) ||
800 (t == TypeManager.short_type) ||
801 (t == TypeManager.ushort_type) ||
802 (t == TypeManager.int32_type) ||
803 (t == TypeManager.uint32_type) ||
804 (t == TypeManager.int64_type) ||
805 (t == TypeManager.uint64_type) ||
806 (t == TypeManager.char_type) ||
807 (t.IsSubclassOf (TypeManager.enum_type)) ||
808 (t == TypeManager.float_type) ||
809 (t == TypeManager.double_type) ||
810 (t.IsPointer && t != TypeManager.void_ptr_type);
813 Expression ResolveOperator (EmitContext ec)
815 Type expr_type = expr.Type;
818 // Step 1: Perform Operator Overload location
823 if (mode == Mode.PreIncrement || mode == Mode.PostIncrement)
824 op_name = "op_Increment";
826 op_name = "op_Decrement";
828 mg = MemberLookup (ec, expr_type, op_name, MemberTypes.Method, AllBindingFlags, loc);
830 if (mg == null && expr_type.BaseType != null)
831 mg = MemberLookup (ec, expr_type.BaseType, op_name,
832 MemberTypes.Method, AllBindingFlags, loc);
835 method = StaticCallExpr.MakeSimpleCall (
836 ec, (MethodGroupExpr) mg, expr, loc);
843 // The operand of the prefix/postfix increment decrement operators
844 // should be an expression that is classified as a variable,
845 // a property access or an indexer access
848 if (expr.eclass == ExprClass.Variable){
849 LocalVariableReference var = expr as LocalVariableReference;
850 if ((var != null) && var.IsReadOnly)
851 Error (1604, "cannot assign to `" + var.Name + "' because it is readonly");
852 if (IsIncrementableNumber (expr_type) ||
853 expr_type == TypeManager.decimal_type){
856 } else if (expr.eclass == ExprClass.IndexerAccess){
857 IndexerAccess ia = (IndexerAccess) expr;
859 temp_storage = new LocalTemporary (ec, expr.Type);
861 expr = ia.ResolveLValue (ec, temp_storage);
866 } else if (expr.eclass == ExprClass.PropertyAccess){
867 PropertyExpr pe = (PropertyExpr) expr;
869 if (pe.VerifyAssignable ())
874 expr.Error_UnexpectedKind ("variable, indexer or property access");
878 Error (187, "No such operator '" + OperName (mode) + "' defined for type '" +
879 TypeManager.CSharpName (expr_type) + "'");
883 public override Expression DoResolve (EmitContext ec)
885 expr = expr.Resolve (ec);
890 eclass = ExprClass.Value;
891 return ResolveOperator (ec);
894 static int PtrTypeSize (Type t)
896 return GetTypeSize (TypeManager.GetElementType (t));
900 // Loads the proper "1" into the stack based on the type, then it emits the
901 // opcode for the operation requested
903 void LoadOneAndEmitOp (EmitContext ec, Type t)
906 // Measure if getting the typecode and using that is more/less efficient
907 // that comparing types. t.GetTypeCode() is an internal call.
909 ILGenerator ig = ec.ig;
911 if (t == TypeManager.uint64_type || t == TypeManager.int64_type)
912 LongConstant.EmitLong (ig, 1);
913 else if (t == TypeManager.double_type)
914 ig.Emit (OpCodes.Ldc_R8, 1.0);
915 else if (t == TypeManager.float_type)
916 ig.Emit (OpCodes.Ldc_R4, 1.0F);
917 else if (t.IsPointer){
918 int n = PtrTypeSize (t);
921 ig.Emit (OpCodes.Sizeof, t);
923 IntConstant.EmitInt (ig, n);
925 ig.Emit (OpCodes.Ldc_I4_1);
928 // Now emit the operation
931 if (t == TypeManager.int32_type ||
932 t == TypeManager.int64_type){
933 if ((mode & Mode.IsDecrement) != 0)
934 ig.Emit (OpCodes.Sub_Ovf);
936 ig.Emit (OpCodes.Add_Ovf);
937 } else if (t == TypeManager.uint32_type ||
938 t == TypeManager.uint64_type){
939 if ((mode & Mode.IsDecrement) != 0)
940 ig.Emit (OpCodes.Sub_Ovf_Un);
942 ig.Emit (OpCodes.Add_Ovf_Un);
944 if ((mode & Mode.IsDecrement) != 0)
945 ig.Emit (OpCodes.Sub_Ovf);
947 ig.Emit (OpCodes.Add_Ovf);
950 if ((mode & Mode.IsDecrement) != 0)
951 ig.Emit (OpCodes.Sub);
953 ig.Emit (OpCodes.Add);
956 if (t == TypeManager.sbyte_type){
958 ig.Emit (OpCodes.Conv_Ovf_I1);
960 ig.Emit (OpCodes.Conv_I1);
961 } else if (t == TypeManager.byte_type){
963 ig.Emit (OpCodes.Conv_Ovf_U1);
965 ig.Emit (OpCodes.Conv_U1);
966 } else if (t == TypeManager.short_type){
968 ig.Emit (OpCodes.Conv_Ovf_I2);
970 ig.Emit (OpCodes.Conv_I2);
971 } else if (t == TypeManager.ushort_type || t == TypeManager.char_type){
973 ig.Emit (OpCodes.Conv_Ovf_U2);
975 ig.Emit (OpCodes.Conv_U2);
980 static EmptyExpression empty_expr;
982 void EmitCode (EmitContext ec, bool is_expr)
984 ILGenerator ig = ec.ig;
985 IAssignMethod ia = (IAssignMethod) expr;
986 Type expr_type = expr.Type;
988 ia.CacheTemporaries (ec);
991 // NOTE: We should probably handle three cases:
993 // * method invocation required.
994 // * direct stack manipulation possible
995 // * the object requires an "instance" field
997 if (temp_storage == null){
999 // Temporary improvement: if we are dealing with something that does
1000 // not require complicated instance setup, avoid using a temporary
1002 // For now: only localvariables when not remapped
1005 if (method == null &&
1006 ((expr is LocalVariableReference) ||(expr is FieldExpr && ((FieldExpr) expr).FieldInfo.IsStatic))){
1007 if (empty_expr == null)
1008 empty_expr = new EmptyExpression ();
1011 case Mode.PreIncrement:
1012 case Mode.PreDecrement:
1015 LoadOneAndEmitOp (ec, expr_type);
1017 ig.Emit (OpCodes.Dup);
1018 ia.EmitAssign (ec, empty_expr);
1021 case Mode.PostIncrement:
1022 case Mode.PostDecrement:
1025 ig.Emit (OpCodes.Dup);
1027 LoadOneAndEmitOp (ec, expr_type);
1028 ia.EmitAssign (ec, empty_expr);
1033 temp_storage = new LocalTemporary (ec, expr_type);
1037 case Mode.PreIncrement:
1038 case Mode.PreDecrement:
1039 if (method == null){
1042 LoadOneAndEmitOp (ec, expr_type);
1046 temp_storage.Store (ec);
1047 ia.EmitAssign (ec, temp_storage);
1049 temp_storage.Emit (ec);
1052 case Mode.PostIncrement:
1053 case Mode.PostDecrement:
1057 if (method == null){
1061 ig.Emit (OpCodes.Dup);
1063 LoadOneAndEmitOp (ec, expr_type);
1068 temp_storage.Store (ec);
1069 ia.EmitAssign (ec, temp_storage);
1073 temp_storage.Release (ec);
1076 public override void Emit (EmitContext ec)
1078 EmitCode (ec, true);
1082 public override void EmitStatement (EmitContext ec)
1084 EmitCode (ec, false);
1090 /// Base class for the `Is' and `As' classes.
1094 /// FIXME: Split this in two, and we get to save the `Operator' Oper
1097 public abstract class Probe : Expression {
1098 public readonly Expression ProbeType;
1099 protected Expression expr;
1100 protected Type probe_type;
1102 public Probe (Expression expr, Expression probe_type, Location l)
1104 ProbeType = probe_type;
1109 public Expression Expr {
1115 public override Expression DoResolve (EmitContext ec)
1117 probe_type = ec.DeclSpace.ResolveType (ProbeType, false, loc);
1119 if (probe_type == null)
1122 CheckObsoleteAttribute (probe_type);
1124 expr = expr.Resolve (ec);
1133 /// Implementation of the `is' operator.
1135 public class Is : Probe {
1136 public Is (Expression expr, Expression probe_type, Location l)
1137 : base (expr, probe_type, l)
1142 AlwaysTrue, AlwaysNull, AlwaysFalse, LeaveOnStack, Probe
1147 public override void Emit (EmitContext ec)
1149 ILGenerator ig = ec.ig;
1154 case Action.AlwaysFalse:
1155 ig.Emit (OpCodes.Pop);
1156 IntConstant.EmitInt (ig, 0);
1158 case Action.AlwaysTrue:
1159 ig.Emit (OpCodes.Pop);
1160 IntConstant.EmitInt (ig, 1);
1162 case Action.LeaveOnStack:
1163 // the `e != null' rule.
1164 ig.Emit (OpCodes.Ldnull);
1165 ig.Emit (OpCodes.Ceq);
1166 ig.Emit (OpCodes.Ldc_I4_0);
1167 ig.Emit (OpCodes.Ceq);
1170 ig.Emit (OpCodes.Isinst, probe_type);
1171 ig.Emit (OpCodes.Ldnull);
1172 ig.Emit (OpCodes.Cgt_Un);
1175 throw new Exception ("never reached");
1178 public override void EmitBranchable (EmitContext ec, Label target, bool onTrue)
1180 ILGenerator ig = ec.ig;
1183 case Action.AlwaysFalse:
1185 ig.Emit (OpCodes.Br, target);
1188 case Action.AlwaysTrue:
1190 ig.Emit (OpCodes.Br, target);
1193 case Action.LeaveOnStack:
1194 // the `e != null' rule.
1196 ig.Emit (onTrue ? OpCodes.Brtrue : OpCodes.Brfalse, target);
1200 ig.Emit (OpCodes.Isinst, probe_type);
1201 ig.Emit (onTrue ? OpCodes.Brtrue : OpCodes.Brfalse, target);
1204 throw new Exception ("never reached");
1207 public override Expression DoResolve (EmitContext ec)
1209 Expression e = base.DoResolve (ec);
1211 if ((e == null) || (expr == null))
1214 Type etype = expr.Type;
1215 bool warning_always_matches = false;
1216 bool warning_never_matches = false;
1218 type = TypeManager.bool_type;
1219 eclass = ExprClass.Value;
1222 // First case, if at compile time, there is an implicit conversion
1223 // then e != null (objects) or true (value types)
1225 e = Convert.ImplicitConversionStandard (ec, expr, probe_type, loc);
1228 if (etype.IsValueType)
1229 action = Action.AlwaysTrue;
1231 action = Action.LeaveOnStack;
1233 warning_always_matches = true;
1234 } else if (Convert.ExplicitReferenceConversionExists (etype, probe_type)){
1236 // Second case: explicit reference convresion
1238 if (expr is NullLiteral)
1239 action = Action.AlwaysFalse;
1241 action = Action.Probe;
1243 action = Action.AlwaysFalse;
1244 warning_never_matches = true;
1247 if (RootContext.WarningLevel >= 1){
1248 if (warning_always_matches)
1249 Warning (183, "The expression is always of type `" +
1250 TypeManager.CSharpName (probe_type) + "'");
1251 else if (warning_never_matches){
1252 if (!(probe_type.IsInterface || expr.Type.IsInterface))
1254 "The expression is never of type `" +
1255 TypeManager.CSharpName (probe_type) + "'");
1264 /// Implementation of the `as' operator.
1266 public class As : Probe {
1267 public As (Expression expr, Expression probe_type, Location l)
1268 : base (expr, probe_type, l)
1272 bool do_isinst = false;
1274 public override void Emit (EmitContext ec)
1276 ILGenerator ig = ec.ig;
1281 ig.Emit (OpCodes.Isinst, probe_type);
1284 static void Error_CannotConvertType (Type source, Type target, Location loc)
1287 39, loc, "as operator can not convert from `" +
1288 TypeManager.CSharpName (source) + "' to `" +
1289 TypeManager.CSharpName (target) + "'");
1292 public override Expression DoResolve (EmitContext ec)
1294 Expression e = base.DoResolve (ec);
1300 eclass = ExprClass.Value;
1301 Type etype = expr.Type;
1303 if (TypeManager.IsValueType (probe_type)){
1304 Report.Error (77, loc, "The as operator should be used with a reference type only (" +
1305 TypeManager.CSharpName (probe_type) + " is a value type)");
1310 e = Convert.ImplicitConversion (ec, expr, probe_type, loc);
1317 if (Convert.ExplicitReferenceConversionExists (etype, probe_type)){
1322 Error_CannotConvertType (etype, probe_type, loc);
1328 /// This represents a typecast in the source language.
1330 /// FIXME: Cast expressions have an unusual set of parsing
1331 /// rules, we need to figure those out.
1333 public class Cast : Expression {
1334 Expression target_type;
1337 public Cast (Expression cast_type, Expression expr, Location loc)
1339 this.target_type = cast_type;
1344 public Expression TargetType {
1350 public Expression Expr {
1359 bool CheckRange (EmitContext ec, long value, Type type, long min, long max)
1361 if (!ec.ConstantCheckState)
1364 if ((value < min) || (value > max)) {
1365 Error (221, "Constant value `" + value + "' cannot be converted " +
1366 "to a `" + TypeManager.CSharpName (type) + "' (use `unchecked' " +
1367 "syntax to override)");
1374 bool CheckRange (EmitContext ec, ulong value, Type type, ulong max)
1376 if (!ec.ConstantCheckState)
1380 Error (221, "Constant value `" + value + "' cannot be converted " +
1381 "to a `" + TypeManager.CSharpName (type) + "' (use `unchecked' " +
1382 "syntax to override)");
1389 bool CheckUnsigned (EmitContext ec, long value, Type type)
1391 if (!ec.ConstantCheckState)
1395 Error (221, "Constant value `" + value + "' cannot be converted " +
1396 "to a `" + TypeManager.CSharpName (type) + "' (use `unchecked' " +
1397 "syntax to override)");
1405 /// Attempts to do a compile-time folding of a constant cast.
1407 Expression TryReduce (EmitContext ec, Type target_type)
1409 Expression real_expr = expr;
1410 if (real_expr is EnumConstant)
1411 real_expr = ((EnumConstant) real_expr).Child;
1413 if (real_expr is ByteConstant){
1414 byte v = ((ByteConstant) real_expr).Value;
1416 if (target_type == TypeManager.sbyte_type) {
1417 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1419 return new SByteConstant ((sbyte) v);
1421 if (target_type == TypeManager.short_type)
1422 return new ShortConstant ((short) v);
1423 if (target_type == TypeManager.ushort_type)
1424 return new UShortConstant ((ushort) v);
1425 if (target_type == TypeManager.int32_type)
1426 return new IntConstant ((int) v);
1427 if (target_type == TypeManager.uint32_type)
1428 return new UIntConstant ((uint) v);
1429 if (target_type == TypeManager.int64_type)
1430 return new LongConstant ((long) v);
1431 if (target_type == TypeManager.uint64_type)
1432 return new ULongConstant ((ulong) v);
1433 if (target_type == TypeManager.float_type)
1434 return new FloatConstant ((float) v);
1435 if (target_type == TypeManager.double_type)
1436 return new DoubleConstant ((double) v);
1437 if (target_type == TypeManager.char_type)
1438 return new CharConstant ((char) v);
1439 if (target_type == TypeManager.decimal_type)
1440 return new DecimalConstant ((decimal) v);
1442 if (real_expr is SByteConstant){
1443 sbyte v = ((SByteConstant) real_expr).Value;
1445 if (target_type == TypeManager.byte_type) {
1446 if (!CheckUnsigned (ec, v, target_type))
1448 return new ByteConstant ((byte) v);
1450 if (target_type == TypeManager.short_type)
1451 return new ShortConstant ((short) v);
1452 if (target_type == TypeManager.ushort_type) {
1453 if (!CheckUnsigned (ec, v, target_type))
1455 return new UShortConstant ((ushort) v);
1456 } if (target_type == TypeManager.int32_type)
1457 return new IntConstant ((int) v);
1458 if (target_type == TypeManager.uint32_type) {
1459 if (!CheckUnsigned (ec, v, target_type))
1461 return new UIntConstant ((uint) v);
1462 } if (target_type == TypeManager.int64_type)
1463 return new LongConstant ((long) v);
1464 if (target_type == TypeManager.uint64_type) {
1465 if (!CheckUnsigned (ec, v, target_type))
1467 return new ULongConstant ((ulong) v);
1469 if (target_type == TypeManager.float_type)
1470 return new FloatConstant ((float) v);
1471 if (target_type == TypeManager.double_type)
1472 return new DoubleConstant ((double) v);
1473 if (target_type == TypeManager.char_type) {
1474 if (!CheckUnsigned (ec, v, target_type))
1476 return new CharConstant ((char) v);
1478 if (target_type == TypeManager.decimal_type)
1479 return new DecimalConstant ((decimal) v);
1481 if (real_expr is ShortConstant){
1482 short v = ((ShortConstant) real_expr).Value;
1484 if (target_type == TypeManager.byte_type) {
1485 if (!CheckRange (ec, v, target_type, Byte.MinValue, Byte.MaxValue))
1487 return new ByteConstant ((byte) v);
1489 if (target_type == TypeManager.sbyte_type) {
1490 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1492 return new SByteConstant ((sbyte) v);
1494 if (target_type == TypeManager.ushort_type) {
1495 if (!CheckUnsigned (ec, v, target_type))
1497 return new UShortConstant ((ushort) v);
1499 if (target_type == TypeManager.int32_type)
1500 return new IntConstant ((int) v);
1501 if (target_type == TypeManager.uint32_type) {
1502 if (!CheckUnsigned (ec, v, target_type))
1504 return new UIntConstant ((uint) v);
1506 if (target_type == TypeManager.int64_type)
1507 return new LongConstant ((long) v);
1508 if (target_type == TypeManager.uint64_type) {
1509 if (!CheckUnsigned (ec, v, target_type))
1511 return new ULongConstant ((ulong) v);
1513 if (target_type == TypeManager.float_type)
1514 return new FloatConstant ((float) v);
1515 if (target_type == TypeManager.double_type)
1516 return new DoubleConstant ((double) v);
1517 if (target_type == TypeManager.char_type) {
1518 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1520 return new CharConstant ((char) v);
1522 if (target_type == TypeManager.decimal_type)
1523 return new DecimalConstant ((decimal) v);
1525 if (real_expr is UShortConstant){
1526 ushort v = ((UShortConstant) real_expr).Value;
1528 if (target_type == TypeManager.byte_type) {
1529 if (!CheckRange (ec, v, target_type, Byte.MinValue, Byte.MaxValue))
1531 return new ByteConstant ((byte) v);
1533 if (target_type == TypeManager.sbyte_type) {
1534 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1536 return new SByteConstant ((sbyte) v);
1538 if (target_type == TypeManager.short_type) {
1539 if (!CheckRange (ec, v, target_type, Int16.MinValue, Int16.MaxValue))
1541 return new ShortConstant ((short) v);
1543 if (target_type == TypeManager.int32_type)
1544 return new IntConstant ((int) v);
1545 if (target_type == TypeManager.uint32_type)
1546 return new UIntConstant ((uint) v);
1547 if (target_type == TypeManager.int64_type)
1548 return new LongConstant ((long) v);
1549 if (target_type == TypeManager.uint64_type)
1550 return new ULongConstant ((ulong) v);
1551 if (target_type == TypeManager.float_type)
1552 return new FloatConstant ((float) v);
1553 if (target_type == TypeManager.double_type)
1554 return new DoubleConstant ((double) v);
1555 if (target_type == TypeManager.char_type) {
1556 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1558 return new CharConstant ((char) v);
1560 if (target_type == TypeManager.decimal_type)
1561 return new DecimalConstant ((decimal) v);
1563 if (real_expr is IntConstant){
1564 int v = ((IntConstant) real_expr).Value;
1566 if (target_type == TypeManager.byte_type) {
1567 if (!CheckRange (ec, v, target_type, Byte.MinValue, Byte.MaxValue))
1569 return new ByteConstant ((byte) v);
1571 if (target_type == TypeManager.sbyte_type) {
1572 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1574 return new SByteConstant ((sbyte) v);
1576 if (target_type == TypeManager.short_type) {
1577 if (!CheckRange (ec, v, target_type, Int16.MinValue, Int16.MaxValue))
1579 return new ShortConstant ((short) v);
1581 if (target_type == TypeManager.ushort_type) {
1582 if (!CheckRange (ec, v, target_type, UInt16.MinValue, UInt16.MaxValue))
1584 return new UShortConstant ((ushort) v);
1586 if (target_type == TypeManager.uint32_type) {
1587 if (!CheckRange (ec, v, target_type, Int32.MinValue, Int32.MaxValue))
1589 return new UIntConstant ((uint) v);
1591 if (target_type == TypeManager.int64_type)
1592 return new LongConstant ((long) v);
1593 if (target_type == TypeManager.uint64_type) {
1594 if (!CheckUnsigned (ec, v, target_type))
1596 return new ULongConstant ((ulong) v);
1598 if (target_type == TypeManager.float_type)
1599 return new FloatConstant ((float) v);
1600 if (target_type == TypeManager.double_type)
1601 return new DoubleConstant ((double) v);
1602 if (target_type == TypeManager.char_type) {
1603 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1605 return new CharConstant ((char) v);
1607 if (target_type == TypeManager.decimal_type)
1608 return new DecimalConstant ((decimal) v);
1610 if (real_expr is UIntConstant){
1611 uint v = ((UIntConstant) real_expr).Value;
1613 if (target_type == TypeManager.byte_type) {
1614 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1616 return new ByteConstant ((byte) v);
1618 if (target_type == TypeManager.sbyte_type) {
1619 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1621 return new SByteConstant ((sbyte) v);
1623 if (target_type == TypeManager.short_type) {
1624 if (!CheckRange (ec, v, target_type, Int16.MinValue, Int16.MaxValue))
1626 return new ShortConstant ((short) v);
1628 if (target_type == TypeManager.ushort_type) {
1629 if (!CheckRange (ec, v, target_type, UInt16.MinValue, UInt16.MaxValue))
1631 return new UShortConstant ((ushort) v);
1633 if (target_type == TypeManager.int32_type) {
1634 if (!CheckRange (ec, v, target_type, Int32.MinValue, Int32.MaxValue))
1636 return new IntConstant ((int) v);
1638 if (target_type == TypeManager.int64_type)
1639 return new LongConstant ((long) v);
1640 if (target_type == TypeManager.uint64_type)
1641 return new ULongConstant ((ulong) v);
1642 if (target_type == TypeManager.float_type)
1643 return new FloatConstant ((float) v);
1644 if (target_type == TypeManager.double_type)
1645 return new DoubleConstant ((double) v);
1646 if (target_type == TypeManager.char_type) {
1647 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1649 return new CharConstant ((char) v);
1651 if (target_type == TypeManager.decimal_type)
1652 return new DecimalConstant ((decimal) v);
1654 if (real_expr is LongConstant){
1655 long v = ((LongConstant) real_expr).Value;
1657 if (target_type == TypeManager.byte_type) {
1658 if (!CheckRange (ec, v, target_type, Byte.MinValue, Byte.MaxValue))
1660 return new ByteConstant ((byte) v);
1662 if (target_type == TypeManager.sbyte_type) {
1663 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1665 return new SByteConstant ((sbyte) v);
1667 if (target_type == TypeManager.short_type) {
1668 if (!CheckRange (ec, v, target_type, Int16.MinValue, Int16.MaxValue))
1670 return new ShortConstant ((short) v);
1672 if (target_type == TypeManager.ushort_type) {
1673 if (!CheckRange (ec, v, target_type, UInt16.MinValue, UInt16.MaxValue))
1675 return new UShortConstant ((ushort) v);
1677 if (target_type == TypeManager.int32_type) {
1678 if (!CheckRange (ec, v, target_type, Int32.MinValue, Int32.MaxValue))
1680 return new IntConstant ((int) v);
1682 if (target_type == TypeManager.uint32_type) {
1683 if (!CheckRange (ec, v, target_type, UInt32.MinValue, UInt32.MaxValue))
1685 return new UIntConstant ((uint) v);
1687 if (target_type == TypeManager.uint64_type) {
1688 if (!CheckUnsigned (ec, v, target_type))
1690 return new ULongConstant ((ulong) v);
1692 if (target_type == TypeManager.float_type)
1693 return new FloatConstant ((float) v);
1694 if (target_type == TypeManager.double_type)
1695 return new DoubleConstant ((double) v);
1696 if (target_type == TypeManager.char_type) {
1697 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1699 return new CharConstant ((char) v);
1701 if (target_type == TypeManager.decimal_type)
1702 return new DecimalConstant ((decimal) v);
1704 if (real_expr is ULongConstant){
1705 ulong v = ((ULongConstant) real_expr).Value;
1707 if (target_type == TypeManager.byte_type) {
1708 if (!CheckRange (ec, v, target_type, Byte.MaxValue))
1710 return new ByteConstant ((byte) v);
1712 if (target_type == TypeManager.sbyte_type) {
1713 if (!CheckRange (ec, v, target_type, (ulong) SByte.MaxValue))
1715 return new SByteConstant ((sbyte) v);
1717 if (target_type == TypeManager.short_type) {
1718 if (!CheckRange (ec, v, target_type, (ulong) Int16.MaxValue))
1720 return new ShortConstant ((short) v);
1722 if (target_type == TypeManager.ushort_type) {
1723 if (!CheckRange (ec, v, target_type, UInt16.MaxValue))
1725 return new UShortConstant ((ushort) v);
1727 if (target_type == TypeManager.int32_type) {
1728 if (!CheckRange (ec, v, target_type, Int32.MaxValue))
1730 return new IntConstant ((int) v);
1732 if (target_type == TypeManager.uint32_type) {
1733 if (!CheckRange (ec, v, target_type, UInt32.MaxValue))
1735 return new UIntConstant ((uint) v);
1737 if (target_type == TypeManager.int64_type) {
1738 if (!CheckRange (ec, v, target_type, (ulong) Int64.MaxValue))
1740 return new LongConstant ((long) v);
1742 if (target_type == TypeManager.float_type)
1743 return new FloatConstant ((float) v);
1744 if (target_type == TypeManager.double_type)
1745 return new DoubleConstant ((double) v);
1746 if (target_type == TypeManager.char_type) {
1747 if (!CheckRange (ec, v, target_type, Char.MaxValue))
1749 return new CharConstant ((char) v);
1751 if (target_type == TypeManager.decimal_type)
1752 return new DecimalConstant ((decimal) v);
1754 if (real_expr is FloatConstant){
1755 float v = ((FloatConstant) real_expr).Value;
1757 if (target_type == TypeManager.byte_type)
1758 return new ByteConstant ((byte) v);
1759 if (target_type == TypeManager.sbyte_type)
1760 return new SByteConstant ((sbyte) v);
1761 if (target_type == TypeManager.short_type)
1762 return new ShortConstant ((short) v);
1763 if (target_type == TypeManager.ushort_type)
1764 return new UShortConstant ((ushort) v);
1765 if (target_type == TypeManager.int32_type)
1766 return new IntConstant ((int) v);
1767 if (target_type == TypeManager.uint32_type)
1768 return new UIntConstant ((uint) v);
1769 if (target_type == TypeManager.int64_type)
1770 return new LongConstant ((long) v);
1771 if (target_type == TypeManager.uint64_type)
1772 return new ULongConstant ((ulong) v);
1773 if (target_type == TypeManager.double_type)
1774 return new DoubleConstant ((double) v);
1775 if (target_type == TypeManager.char_type)
1776 return new CharConstant ((char) v);
1777 if (target_type == TypeManager.decimal_type)
1778 return new DecimalConstant ((decimal) v);
1780 if (real_expr is DoubleConstant){
1781 double v = ((DoubleConstant) real_expr).Value;
1783 if (target_type == TypeManager.byte_type){
1784 return new ByteConstant ((byte) v);
1785 } if (target_type == TypeManager.sbyte_type)
1786 return new SByteConstant ((sbyte) v);
1787 if (target_type == TypeManager.short_type)
1788 return new ShortConstant ((short) v);
1789 if (target_type == TypeManager.ushort_type)
1790 return new UShortConstant ((ushort) v);
1791 if (target_type == TypeManager.int32_type)
1792 return new IntConstant ((int) v);
1793 if (target_type == TypeManager.uint32_type)
1794 return new UIntConstant ((uint) v);
1795 if (target_type == TypeManager.int64_type)
1796 return new LongConstant ((long) v);
1797 if (target_type == TypeManager.uint64_type)
1798 return new ULongConstant ((ulong) v);
1799 if (target_type == TypeManager.float_type)
1800 return new FloatConstant ((float) v);
1801 if (target_type == TypeManager.char_type)
1802 return new CharConstant ((char) v);
1803 if (target_type == TypeManager.decimal_type)
1804 return new DecimalConstant ((decimal) v);
1807 if (real_expr is CharConstant){
1808 char v = ((CharConstant) real_expr).Value;
1810 if (target_type == TypeManager.byte_type) {
1811 if (!CheckRange (ec, v, target_type, Byte.MinValue, Byte.MaxValue))
1813 return new ByteConstant ((byte) v);
1815 if (target_type == TypeManager.sbyte_type) {
1816 if (!CheckRange (ec, v, target_type, SByte.MinValue, SByte.MaxValue))
1818 return new SByteConstant ((sbyte) v);
1820 if (target_type == TypeManager.short_type) {
1821 if (!CheckRange (ec, v, target_type, Int16.MinValue, Int16.MaxValue))
1823 return new ShortConstant ((short) v);
1825 if (target_type == TypeManager.int32_type)
1826 return new IntConstant ((int) v);
1827 if (target_type == TypeManager.uint32_type)
1828 return new UIntConstant ((uint) v);
1829 if (target_type == TypeManager.int64_type)
1830 return new LongConstant ((long) v);
1831 if (target_type == TypeManager.uint64_type)
1832 return new ULongConstant ((ulong) v);
1833 if (target_type == TypeManager.float_type)
1834 return new FloatConstant ((float) v);
1835 if (target_type == TypeManager.double_type)
1836 return new DoubleConstant ((double) v);
1837 if (target_type == TypeManager.char_type) {
1838 if (!CheckRange (ec, v, target_type, Char.MinValue, Char.MaxValue))
1840 return new CharConstant ((char) v);
1842 if (target_type == TypeManager.decimal_type)
1843 return new DecimalConstant ((decimal) v);
1849 public override Expression DoResolve (EmitContext ec)
1851 expr = expr.Resolve (ec);
1855 type = ec.DeclSpace.ResolveType (target_type, false, Location);
1860 CheckObsoleteAttribute (type);
1862 eclass = ExprClass.Value;
1864 if (expr is Constant){
1865 Expression e = TryReduce (ec, type);
1871 if (type.IsPointer && !ec.InUnsafe) {
1875 expr = Convert.ExplicitConversion (ec, expr, type, loc);
1879 public override void Emit (EmitContext ec)
1882 // This one will never happen
1884 throw new Exception ("Should not happen");
1889 /// Binary operators
1891 public class Binary : Expression {
1892 public enum Operator : byte {
1893 Multiply, Division, Modulus,
1894 Addition, Subtraction,
1895 LeftShift, RightShift,
1896 LessThan, GreaterThan, LessThanOrEqual, GreaterThanOrEqual,
1897 Equality, Inequality,
1907 Expression left, right;
1909 // This must be kept in sync with Operator!!!
1910 public static readonly string [] oper_names;
1914 oper_names = new string [(int) Operator.TOP];
1916 oper_names [(int) Operator.Multiply] = "op_Multiply";
1917 oper_names [(int) Operator.Division] = "op_Division";
1918 oper_names [(int) Operator.Modulus] = "op_Modulus";
1919 oper_names [(int) Operator.Addition] = "op_Addition";
1920 oper_names [(int) Operator.Subtraction] = "op_Subtraction";
1921 oper_names [(int) Operator.LeftShift] = "op_LeftShift";
1922 oper_names [(int) Operator.RightShift] = "op_RightShift";
1923 oper_names [(int) Operator.LessThan] = "op_LessThan";
1924 oper_names [(int) Operator.GreaterThan] = "op_GreaterThan";
1925 oper_names [(int) Operator.LessThanOrEqual] = "op_LessThanOrEqual";
1926 oper_names [(int) Operator.GreaterThanOrEqual] = "op_GreaterThanOrEqual";
1927 oper_names [(int) Operator.Equality] = "op_Equality";
1928 oper_names [(int) Operator.Inequality] = "op_Inequality";
1929 oper_names [(int) Operator.BitwiseAnd] = "op_BitwiseAnd";
1930 oper_names [(int) Operator.BitwiseOr] = "op_BitwiseOr";
1931 oper_names [(int) Operator.ExclusiveOr] = "op_ExclusiveOr";
1932 oper_names [(int) Operator.LogicalOr] = "op_LogicalOr";
1933 oper_names [(int) Operator.LogicalAnd] = "op_LogicalAnd";
1936 public Binary (Operator oper, Expression left, Expression right, Location loc)
1944 public Operator Oper {
1953 public Expression Left {
1962 public Expression Right {
1973 /// Returns a stringified representation of the Operator
1975 static string OperName (Operator oper)
1978 case Operator.Multiply:
1980 case Operator.Division:
1982 case Operator.Modulus:
1984 case Operator.Addition:
1986 case Operator.Subtraction:
1988 case Operator.LeftShift:
1990 case Operator.RightShift:
1992 case Operator.LessThan:
1994 case Operator.GreaterThan:
1996 case Operator.LessThanOrEqual:
1998 case Operator.GreaterThanOrEqual:
2000 case Operator.Equality:
2002 case Operator.Inequality:
2004 case Operator.BitwiseAnd:
2006 case Operator.BitwiseOr:
2008 case Operator.ExclusiveOr:
2010 case Operator.LogicalOr:
2012 case Operator.LogicalAnd:
2016 return oper.ToString ();
2019 public override string ToString ()
2021 return "operator " + OperName (oper) + "(" + left.ToString () + ", " +
2022 right.ToString () + ")";
2025 Expression ForceConversion (EmitContext ec, Expression expr, Type target_type)
2027 if (expr.Type == target_type)
2030 return Convert.ImplicitConversion (ec, expr, target_type, loc);
2033 public static void Error_OperatorAmbiguous (Location loc, Operator oper, Type l, Type r)
2036 34, loc, "Operator `" + OperName (oper)
2037 + "' is ambiguous on operands of type `"
2038 + TypeManager.CSharpName (l) + "' "
2039 + "and `" + TypeManager.CSharpName (r)
2043 bool IsOfType (EmitContext ec, Type l, Type r, Type t, bool check_user_conversions)
2045 if ((l == t) || (r == t))
2048 if (!check_user_conversions)
2051 if (Convert.ImplicitUserConversionExists (ec, l, t))
2053 else if (Convert.ImplicitUserConversionExists (ec, r, t))
2060 // Note that handling the case l == Decimal || r == Decimal
2061 // is taken care of by the Step 1 Operator Overload resolution.
2063 // If `check_user_conv' is true, we also check whether a user-defined conversion
2064 // exists. Note that we only need to do this if both arguments are of a user-defined
2065 // type, otherwise ConvertImplict() already finds the user-defined conversion for us,
2066 // so we don't explicitly check for performance reasons.
2068 bool DoNumericPromotions (EmitContext ec, Type l, Type r, bool check_user_conv)
2070 if (IsOfType (ec, l, r, TypeManager.double_type, check_user_conv)){
2072 // If either operand is of type double, the other operand is
2073 // conveted to type double.
2075 if (r != TypeManager.double_type)
2076 right = Convert.ImplicitConversion (ec, right, TypeManager.double_type, loc);
2077 if (l != TypeManager.double_type)
2078 left = Convert.ImplicitConversion (ec, left, TypeManager.double_type, loc);
2080 type = TypeManager.double_type;
2081 } else if (IsOfType (ec, l, r, TypeManager.float_type, check_user_conv)){
2083 // if either operand is of type float, the other operand is
2084 // converted to type float.
2086 if (r != TypeManager.double_type)
2087 right = Convert.ImplicitConversion (ec, right, TypeManager.float_type, loc);
2088 if (l != TypeManager.double_type)
2089 left = Convert.ImplicitConversion (ec, left, TypeManager.float_type, loc);
2090 type = TypeManager.float_type;
2091 } else if (IsOfType (ec, l, r, TypeManager.uint64_type, check_user_conv)){
2095 // If either operand is of type ulong, the other operand is
2096 // converted to type ulong. or an error ocurrs if the other
2097 // operand is of type sbyte, short, int or long
2099 if (l == TypeManager.uint64_type){
2100 if (r != TypeManager.uint64_type){
2101 if (right is IntConstant){
2102 IntConstant ic = (IntConstant) right;
2104 e = Convert.TryImplicitIntConversion (l, ic);
2107 } else if (right is LongConstant){
2108 long ll = ((LongConstant) right).Value;
2111 right = new ULongConstant ((ulong) ll);
2113 e = Convert.ImplicitNumericConversion (ec, right, l, loc);
2120 if (left is IntConstant){
2121 e = Convert.TryImplicitIntConversion (r, (IntConstant) left);
2124 } else if (left is LongConstant){
2125 long ll = ((LongConstant) left).Value;
2128 left = new ULongConstant ((ulong) ll);
2130 e = Convert.ImplicitNumericConversion (ec, left, r, loc);
2137 if ((other == TypeManager.sbyte_type) ||
2138 (other == TypeManager.short_type) ||
2139 (other == TypeManager.int32_type) ||
2140 (other == TypeManager.int64_type))
2141 Error_OperatorAmbiguous (loc, oper, l, r);
2142 type = TypeManager.uint64_type;
2143 } else if (IsOfType (ec, l, r, TypeManager.int64_type, check_user_conv)){
2145 // If either operand is of type long, the other operand is converted
2148 if (l != TypeManager.int64_type)
2149 left = Convert.ImplicitConversion (ec, left, TypeManager.int64_type, loc);
2150 if (r != TypeManager.int64_type)
2151 right = Convert.ImplicitConversion (ec, right, TypeManager.int64_type, loc);
2153 type = TypeManager.int64_type;
2154 } else if (IsOfType (ec, l, r, TypeManager.uint32_type, check_user_conv)){
2156 // If either operand is of type uint, and the other
2157 // operand is of type sbyte, short or int, othe operands are
2158 // converted to type long (unless we have an int constant).
2162 if (l == TypeManager.uint32_type){
2163 if (right is IntConstant){
2164 IntConstant ic = (IntConstant) right;
2168 right = new UIntConstant ((uint) val);
2175 } else if (r == TypeManager.uint32_type){
2176 if (left is IntConstant){
2177 IntConstant ic = (IntConstant) left;
2181 left = new UIntConstant ((uint) val);
2190 if ((other == TypeManager.sbyte_type) ||
2191 (other == TypeManager.short_type) ||
2192 (other == TypeManager.int32_type)){
2193 left = ForceConversion (ec, left, TypeManager.int64_type);
2194 right = ForceConversion (ec, right, TypeManager.int64_type);
2195 type = TypeManager.int64_type;
2198 // if either operand is of type uint, the other
2199 // operand is converd to type uint
2201 left = ForceConversion (ec, left, TypeManager.uint32_type);
2202 right = ForceConversion (ec, right, TypeManager.uint32_type);
2203 type = TypeManager.uint32_type;
2205 } else if (l == TypeManager.decimal_type || r == TypeManager.decimal_type){
2206 if (l != TypeManager.decimal_type)
2207 left = Convert.ImplicitConversion (ec, left, TypeManager.decimal_type, loc);
2209 if (r != TypeManager.decimal_type)
2210 right = Convert.ImplicitConversion (ec, right, TypeManager.decimal_type, loc);
2211 type = TypeManager.decimal_type;
2213 left = ForceConversion (ec, left, TypeManager.int32_type);
2214 right = ForceConversion (ec, right, TypeManager.int32_type);
2216 type = TypeManager.int32_type;
2219 return (left != null) && (right != null);
2222 static public void Error_OperatorCannotBeApplied (Location loc, string name, Type l, Type r)
2224 Report.Error (19, loc,
2225 "Operator " + name + " cannot be applied to operands of type `" +
2226 TypeManager.CSharpName (l) + "' and `" +
2227 TypeManager.CSharpName (r) + "'");
2230 void Error_OperatorCannotBeApplied ()
2232 Error_OperatorCannotBeApplied (loc, OperName (oper), left.Type, right.Type);
2235 static bool is_unsigned (Type t)
2237 return (t == TypeManager.uint32_type || t == TypeManager.uint64_type ||
2238 t == TypeManager.short_type || t == TypeManager.byte_type);
2241 static bool is_user_defined (Type t)
2243 if (t.IsSubclassOf (TypeManager.value_type) &&
2244 (!TypeManager.IsBuiltinType (t) || t == TypeManager.decimal_type))
2250 Expression Make32or64 (EmitContext ec, Expression e)
2254 if (t == TypeManager.int32_type || t == TypeManager.uint32_type ||
2255 t == TypeManager.int64_type || t == TypeManager.uint64_type)
2257 Expression ee = Convert.ImplicitConversion (ec, e, TypeManager.int32_type, loc);
2260 ee = Convert.ImplicitConversion (ec, e, TypeManager.uint32_type, loc);
2263 ee = Convert.ImplicitConversion (ec, e, TypeManager.int64_type, loc);
2266 ee = Convert.ImplicitConversion (ec, e, TypeManager.uint64_type, loc);
2272 Expression CheckShiftArguments (EmitContext ec)
2276 e = ForceConversion (ec, right, TypeManager.int32_type);
2278 Error_OperatorCannotBeApplied ();
2283 if (((e = Convert.ImplicitConversion (ec, left, TypeManager.int32_type, loc)) != null) ||
2284 ((e = Convert.ImplicitConversion (ec, left, TypeManager.uint32_type, loc)) != null) ||
2285 ((e = Convert.ImplicitConversion (ec, left, TypeManager.int64_type, loc)) != null) ||
2286 ((e = Convert.ImplicitConversion (ec, left, TypeManager.uint64_type, loc)) != null)){
2290 if (type == TypeManager.int32_type || type == TypeManager.uint32_type){
2291 right = new Binary (Binary.Operator.BitwiseAnd, right, new IntLiteral (31), loc);
2292 right = right.DoResolve (ec);
2294 right = new Binary (Binary.Operator.BitwiseAnd, right, new IntLiteral (63), loc);
2295 right = right.DoResolve (ec);
2300 Error_OperatorCannotBeApplied ();
2304 Expression ResolveOperator (EmitContext ec)
2307 Type r = right.Type;
2309 bool overload_failed = false;
2312 // Special cases: string or type parameter comapred to null
2314 if (oper == Operator.Equality || oper == Operator.Inequality){
2315 if ((l == TypeManager.string_type && (right is NullLiteral)) ||
2316 (r == TypeManager.string_type && (left is NullLiteral))){
2317 Type = TypeManager.bool_type;
2322 if (l.IsGenericParameter && (right is NullLiteral)) {
2323 if (l.BaseType == TypeManager.value_type) {
2324 Error_OperatorCannotBeApplied ();
2328 left = new BoxedCast (left);
2329 Type = TypeManager.bool_type;
2333 if (r.IsGenericParameter && (left is NullLiteral)) {
2334 if (r.BaseType == TypeManager.value_type) {
2335 Error_OperatorCannotBeApplied ();
2339 right = new BoxedCast (right);
2340 Type = TypeManager.bool_type;
2345 if (l == TypeManager.intptr_type && r == TypeManager.intptr_type) {
2346 Type = TypeManager.bool_type;
2353 // Do not perform operator overload resolution when both sides are
2356 if (!(TypeManager.IsCLRType (l) && TypeManager.IsCLRType (r))){
2358 // Step 1: Perform Operator Overload location
2360 Expression left_expr, right_expr;
2362 string op = oper_names [(int) oper];
2364 MethodGroupExpr union;
2365 left_expr = MemberLookup (ec, l, op, MemberTypes.Method, AllBindingFlags, loc);
2367 right_expr = MemberLookup (
2368 ec, r, op, MemberTypes.Method, AllBindingFlags, loc);
2369 union = Invocation.MakeUnionSet (left_expr, right_expr, loc);
2371 union = (MethodGroupExpr) left_expr;
2373 if (union != null) {
2374 ArrayList args = new ArrayList (2);
2375 args.Add (new Argument (left, Argument.AType.Expression));
2376 args.Add (new Argument (right, Argument.AType.Expression));
2378 MethodBase method = Invocation.OverloadResolve (
2379 ec, union, args, true, Location.Null);
2381 if (method != null) {
2382 MethodInfo mi = (MethodInfo) method;
2384 return new BinaryMethod (mi.ReturnType, method, args);
2386 overload_failed = true;
2392 // Step 0: String concatenation (because overloading will get this wrong)
2394 if (oper == Operator.Addition){
2396 // If any of the arguments is a string, cast to string
2399 // Simple constant folding
2400 if (left is StringConstant && right is StringConstant)
2401 return new StringConstant (((StringConstant) left).Value + ((StringConstant) right).Value);
2403 if (l == TypeManager.string_type || r == TypeManager.string_type) {
2405 if (r == TypeManager.void_type || l == TypeManager.void_type) {
2406 Error_OperatorCannotBeApplied ();
2410 // try to fold it in on the left
2411 if (left is StringConcat) {
2414 // We have to test here for not-null, since we can be doubly-resolved
2415 // take care of not appending twice
2418 type = TypeManager.string_type;
2419 ((StringConcat) left).Append (ec, right);
2420 return left.Resolve (ec);
2426 // Otherwise, start a new concat expression
2427 return new StringConcat (ec, loc, left, right).Resolve (ec);
2431 // Transform a + ( - b) into a - b
2433 if (right is Unary){
2434 Unary right_unary = (Unary) right;
2436 if (right_unary.Oper == Unary.Operator.UnaryNegation){
2437 oper = Operator.Subtraction;
2438 right = right_unary.Expr;
2444 if (oper == Operator.Equality || oper == Operator.Inequality){
2445 if (l == TypeManager.bool_type || r == TypeManager.bool_type){
2446 if (r != TypeManager.bool_type || l != TypeManager.bool_type){
2447 Error_OperatorCannotBeApplied ();
2451 type = TypeManager.bool_type;
2456 // operator != (object a, object b)
2457 // operator == (object a, object b)
2459 // For this to be used, both arguments have to be reference-types.
2460 // Read the rationale on the spec (14.9.6)
2462 // Also, if at compile time we know that the classes do not inherit
2463 // one from the other, then we catch the error there.
2465 if (!(l.IsValueType || r.IsValueType)){
2466 type = TypeManager.bool_type;
2471 if (l.IsSubclassOf (r) || r.IsSubclassOf (l))
2475 // Also, a standard conversion must exist from either one
2477 if (!(Convert.ImplicitStandardConversionExists (left, r) ||
2478 Convert.ImplicitStandardConversionExists (right, l))){
2479 Error_OperatorCannotBeApplied ();
2483 // We are going to have to convert to an object to compare
2485 if (l != TypeManager.object_type)
2486 left = new EmptyCast (left, TypeManager.object_type);
2487 if (r != TypeManager.object_type)
2488 right = new EmptyCast (right, TypeManager.object_type);
2491 // FIXME: CSC here catches errors cs254 and cs252
2497 // One of them is a valuetype, but the other one is not.
2499 if (!l.IsValueType || !r.IsValueType) {
2500 Error_OperatorCannotBeApplied ();
2505 // Only perform numeric promotions on:
2506 // +, -, *, /, %, &, |, ^, ==, !=, <, >, <=, >=
2508 if (oper == Operator.Addition || oper == Operator.Subtraction) {
2509 if (TypeManager.IsDelegateType (l)){
2510 if (right.eclass == ExprClass.MethodGroup && RootContext.V2){
2511 Expression tmp = Convert.ImplicitConversionRequired (ec, right, l, loc);
2518 if (TypeManager.IsDelegateType (r)){
2520 ArrayList args = new ArrayList (2);
2522 args = new ArrayList (2);
2523 args.Add (new Argument (left, Argument.AType.Expression));
2524 args.Add (new Argument (right, Argument.AType.Expression));
2526 if (oper == Operator.Addition)
2527 method = TypeManager.delegate_combine_delegate_delegate;
2529 method = TypeManager.delegate_remove_delegate_delegate;
2532 Error_OperatorCannotBeApplied ();
2536 return new BinaryDelegate (l, method, args);
2541 // Pointer arithmetic:
2543 // T* operator + (T* x, int y);
2544 // T* operator + (T* x, uint y);
2545 // T* operator + (T* x, long y);
2546 // T* operator + (T* x, ulong y);
2548 // T* operator + (int y, T* x);
2549 // T* operator + (uint y, T *x);
2550 // T* operator + (long y, T *x);
2551 // T* operator + (ulong y, T *x);
2553 // T* operator - (T* x, int y);
2554 // T* operator - (T* x, uint y);
2555 // T* operator - (T* x, long y);
2556 // T* operator - (T* x, ulong y);
2558 // long operator - (T* x, T *y)
2561 if (r.IsPointer && oper == Operator.Subtraction){
2563 return new PointerArithmetic (
2564 false, left, right, TypeManager.int64_type,
2567 Expression t = Make32or64 (ec, right);
2569 return new PointerArithmetic (oper == Operator.Addition, left, t, l, loc);
2571 } else if (r.IsPointer && oper == Operator.Addition){
2572 Expression t = Make32or64 (ec, left);
2574 return new PointerArithmetic (true, right, t, r, loc);
2579 // Enumeration operators
2581 bool lie = TypeManager.IsEnumType (l);
2582 bool rie = TypeManager.IsEnumType (r);
2586 // U operator - (E e, E f)
2588 if (oper == Operator.Subtraction){
2590 type = TypeManager.EnumToUnderlying (l);
2593 Error_OperatorCannotBeApplied ();
2599 // operator + (E e, U x)
2600 // operator - (E e, U x)
2602 if (oper == Operator.Addition || oper == Operator.Subtraction){
2603 Type enum_type = lie ? l : r;
2604 Type other_type = lie ? r : l;
2605 Type underlying_type = TypeManager.EnumToUnderlying (enum_type);
2607 if (underlying_type != other_type){
2608 temp = Convert.ImplicitConversion (ec, lie ? right : left, underlying_type, loc);
2618 Error_OperatorCannotBeApplied ();
2627 temp = Convert.ImplicitConversion (ec, right, l, loc);
2631 Error_OperatorCannotBeApplied ();
2635 temp = Convert.ImplicitConversion (ec, left, r, loc);
2640 Error_OperatorCannotBeApplied ();
2645 if (oper == Operator.Equality || oper == Operator.Inequality ||
2646 oper == Operator.LessThanOrEqual || oper == Operator.LessThan ||
2647 oper == Operator.GreaterThanOrEqual || oper == Operator.GreaterThan){
2648 if (left.Type != right.Type){
2649 Error_OperatorCannotBeApplied ();
2652 type = TypeManager.bool_type;
2656 if (oper == Operator.BitwiseAnd ||
2657 oper == Operator.BitwiseOr ||
2658 oper == Operator.ExclusiveOr){
2662 Error_OperatorCannotBeApplied ();
2666 if (oper == Operator.LeftShift || oper == Operator.RightShift)
2667 return CheckShiftArguments (ec);
2669 if (oper == Operator.LogicalOr || oper == Operator.LogicalAnd){
2670 if (l == TypeManager.bool_type && r == TypeManager.bool_type) {
2671 type = TypeManager.bool_type;
2676 Error_OperatorCannotBeApplied ();
2680 Expression e = new ConditionalLogicalOperator (
2681 oper == Operator.LogicalAnd, left, right, l, loc);
2682 return e.Resolve (ec);
2686 // operator & (bool x, bool y)
2687 // operator | (bool x, bool y)
2688 // operator ^ (bool x, bool y)
2690 if (l == TypeManager.bool_type && r == TypeManager.bool_type){
2691 if (oper == Operator.BitwiseAnd ||
2692 oper == Operator.BitwiseOr ||
2693 oper == Operator.ExclusiveOr){
2700 // Pointer comparison
2702 if (l.IsPointer && r.IsPointer){
2703 if (oper == Operator.Equality || oper == Operator.Inequality ||
2704 oper == Operator.LessThan || oper == Operator.LessThanOrEqual ||
2705 oper == Operator.GreaterThan || oper == Operator.GreaterThanOrEqual){
2706 type = TypeManager.bool_type;
2712 // We are dealing with numbers
2714 if (overload_failed){
2715 Error_OperatorCannotBeApplied ();
2720 // This will leave left or right set to null if there is an error
2722 bool check_user_conv = is_user_defined (l) && is_user_defined (r);
2723 DoNumericPromotions (ec, l, r, check_user_conv);
2724 if (left == null || right == null){
2725 Error_OperatorCannotBeApplied (loc, OperName (oper), l, r);
2730 // reload our cached types if required
2735 if (oper == Operator.BitwiseAnd ||
2736 oper == Operator.BitwiseOr ||
2737 oper == Operator.ExclusiveOr){
2739 if (((l == TypeManager.int32_type) ||
2740 (l == TypeManager.uint32_type) ||
2741 (l == TypeManager.short_type) ||
2742 (l == TypeManager.ushort_type) ||
2743 (l == TypeManager.int64_type) ||
2744 (l == TypeManager.uint64_type))){
2747 Error_OperatorCannotBeApplied ();
2751 Error_OperatorCannotBeApplied ();
2756 if (oper == Operator.Equality ||
2757 oper == Operator.Inequality ||
2758 oper == Operator.LessThanOrEqual ||
2759 oper == Operator.LessThan ||
2760 oper == Operator.GreaterThanOrEqual ||
2761 oper == Operator.GreaterThan){
2762 type = TypeManager.bool_type;
2768 public override Expression DoResolve (EmitContext ec)
2770 if ((oper == Operator.Subtraction) && (left is ParenthesizedExpression)) {
2771 left = ((ParenthesizedExpression) left).Expr;
2772 left = left.Resolve (ec, ResolveFlags.VariableOrValue | ResolveFlags.Type);
2776 if (left.eclass == ExprClass.Type) {
2777 Error (75, "Casting a negative value needs to have the value in parentheses.");
2781 left = left.Resolve (ec);
2782 right = right.Resolve (ec);
2784 if (left == null || right == null)
2787 eclass = ExprClass.Value;
2789 Constant rc = right as Constant;
2790 Constant lc = left as Constant;
2792 if (rc != null & lc != null){
2793 Expression e = ConstantFold.BinaryFold (
2794 ec, oper, lc, rc, loc);
2799 return ResolveOperator (ec);
2803 /// EmitBranchable is called from Statement.EmitBoolExpression in the
2804 /// context of a conditional bool expression. This function will return
2805 /// false if it is was possible to use EmitBranchable, or true if it was.
2807 /// The expression's code is generated, and we will generate a branch to `target'
2808 /// if the resulting expression value is equal to isTrue
2810 public override void EmitBranchable (EmitContext ec, Label target, bool onTrue)
2812 ILGenerator ig = ec.ig;
2815 // This is more complicated than it looks, but its just to avoid
2816 // duplicated tests: basically, we allow ==, !=, >, <, >= and <=
2817 // but on top of that we want for == and != to use a special path
2818 // if we are comparing against null
2820 if ((oper == Operator.Equality || oper == Operator.Inequality) && (left is Constant || right is Constant)) {
2821 bool my_on_true = oper == Operator.Inequality ? onTrue : !onTrue;
2824 // put the constant on the rhs, for simplicity
2826 if (left is Constant) {
2827 Expression swap = right;
2832 if (((Constant) right).IsZeroInteger) {
2835 ig.Emit (OpCodes.Brtrue, target);
2837 ig.Emit (OpCodes.Brfalse, target);
2840 } else if (right is BoolConstant){
2842 if (my_on_true != ((BoolConstant) right).Value)
2843 ig.Emit (OpCodes.Brtrue, target);
2845 ig.Emit (OpCodes.Brfalse, target);
2850 } else if (oper == Operator.LogicalAnd) {
2853 Label tests_end = ig.DefineLabel ();
2855 left.EmitBranchable (ec, tests_end, false);
2856 right.EmitBranchable (ec, target, true);
2857 ig.MarkLabel (tests_end);
2859 left.EmitBranchable (ec, target, false);
2860 right.EmitBranchable (ec, target, false);
2865 } else if (oper == Operator.LogicalOr){
2867 left.EmitBranchable (ec, target, true);
2868 right.EmitBranchable (ec, target, true);
2871 Label tests_end = ig.DefineLabel ();
2872 left.EmitBranchable (ec, tests_end, true);
2873 right.EmitBranchable (ec, target, false);
2874 ig.MarkLabel (tests_end);
2879 } else if (!(oper == Operator.LessThan || oper == Operator.GreaterThan ||
2880 oper == Operator.LessThanOrEqual || oper == Operator.GreaterThanOrEqual ||
2881 oper == Operator.Equality || oper == Operator.Inequality)) {
2882 base.EmitBranchable (ec, target, onTrue);
2890 bool isUnsigned = is_unsigned (t) || t == TypeManager.double_type || t == TypeManager.float_type;
2893 case Operator.Equality:
2895 ig.Emit (OpCodes.Beq, target);
2897 ig.Emit (OpCodes.Bne_Un, target);
2900 case Operator.Inequality:
2902 ig.Emit (OpCodes.Bne_Un, target);
2904 ig.Emit (OpCodes.Beq, target);
2907 case Operator.LessThan:
2910 ig.Emit (OpCodes.Blt_Un, target);
2912 ig.Emit (OpCodes.Blt, target);
2915 ig.Emit (OpCodes.Bge_Un, target);
2917 ig.Emit (OpCodes.Bge, target);
2920 case Operator.GreaterThan:
2923 ig.Emit (OpCodes.Bgt_Un, target);
2925 ig.Emit (OpCodes.Bgt, target);
2928 ig.Emit (OpCodes.Ble_Un, target);
2930 ig.Emit (OpCodes.Ble, target);
2933 case Operator.LessThanOrEqual:
2936 ig.Emit (OpCodes.Ble_Un, target);
2938 ig.Emit (OpCodes.Ble, target);
2941 ig.Emit (OpCodes.Bgt_Un, target);
2943 ig.Emit (OpCodes.Bgt, target);
2947 case Operator.GreaterThanOrEqual:
2950 ig.Emit (OpCodes.Bge_Un, target);
2952 ig.Emit (OpCodes.Bge, target);
2955 ig.Emit (OpCodes.Blt_Un, target);
2957 ig.Emit (OpCodes.Blt, target);
2960 Console.WriteLine (oper);
2961 throw new Exception ("what is THAT");
2965 public override void Emit (EmitContext ec)
2967 ILGenerator ig = ec.ig;
2972 // Handle short-circuit operators differently
2975 if (oper == Operator.LogicalAnd) {
2976 Label load_zero = ig.DefineLabel ();
2977 Label end = ig.DefineLabel ();
2979 left.EmitBranchable (ec, load_zero, false);
2981 ig.Emit (OpCodes.Br, end);
2983 ig.MarkLabel (load_zero);
2984 ig.Emit (OpCodes.Ldc_I4_0);
2987 } else if (oper == Operator.LogicalOr) {
2988 Label load_one = ig.DefineLabel ();
2989 Label end = ig.DefineLabel ();
2991 left.EmitBranchable (ec, load_one, true);
2993 ig.Emit (OpCodes.Br, end);
2995 ig.MarkLabel (load_one);
2996 ig.Emit (OpCodes.Ldc_I4_1);
3004 bool isUnsigned = is_unsigned (left.Type);
3007 case Operator.Multiply:
3009 if (l == TypeManager.int32_type || l == TypeManager.int64_type)
3010 opcode = OpCodes.Mul_Ovf;
3011 else if (isUnsigned)
3012 opcode = OpCodes.Mul_Ovf_Un;
3014 opcode = OpCodes.Mul;
3016 opcode = OpCodes.Mul;
3020 case Operator.Division:
3022 opcode = OpCodes.Div_Un;
3024 opcode = OpCodes.Div;
3027 case Operator.Modulus:
3029 opcode = OpCodes.Rem_Un;
3031 opcode = OpCodes.Rem;
3034 case Operator.Addition:
3036 if (l == TypeManager.int32_type || l == TypeManager.int64_type)
3037 opcode = OpCodes.Add_Ovf;
3038 else if (isUnsigned)
3039 opcode = OpCodes.Add_Ovf_Un;
3041 opcode = OpCodes.Add;
3043 opcode = OpCodes.Add;
3046 case Operator.Subtraction:
3048 if (l == TypeManager.int32_type || l == TypeManager.int64_type)
3049 opcode = OpCodes.Sub_Ovf;
3050 else if (isUnsigned)
3051 opcode = OpCodes.Sub_Ovf_Un;
3053 opcode = OpCodes.Sub;
3055 opcode = OpCodes.Sub;
3058 case Operator.RightShift:
3060 opcode = OpCodes.Shr_Un;
3062 opcode = OpCodes.Shr;
3065 case Operator.LeftShift:
3066 opcode = OpCodes.Shl;
3069 case Operator.Equality:
3070 opcode = OpCodes.Ceq;
3073 case Operator.Inequality:
3074 ig.Emit (OpCodes.Ceq);
3075 ig.Emit (OpCodes.Ldc_I4_0);
3077 opcode = OpCodes.Ceq;
3080 case Operator.LessThan:
3082 opcode = OpCodes.Clt_Un;
3084 opcode = OpCodes.Clt;
3087 case Operator.GreaterThan:
3089 opcode = OpCodes.Cgt_Un;
3091 opcode = OpCodes.Cgt;
3094 case Operator.LessThanOrEqual:
3095 Type lt = left.Type;
3097 if (isUnsigned || (lt == TypeManager.double_type || lt == TypeManager.float_type))
3098 ig.Emit (OpCodes.Cgt_Un);
3100 ig.Emit (OpCodes.Cgt);
3101 ig.Emit (OpCodes.Ldc_I4_0);
3103 opcode = OpCodes.Ceq;
3106 case Operator.GreaterThanOrEqual:
3107 Type le = left.Type;
3109 if (isUnsigned || (le == TypeManager.double_type || le == TypeManager.float_type))
3110 ig.Emit (OpCodes.Clt_Un);
3112 ig.Emit (OpCodes.Clt);
3114 ig.Emit (OpCodes.Ldc_I4_0);
3116 opcode = OpCodes.Ceq;
3119 case Operator.BitwiseOr:
3120 opcode = OpCodes.Or;
3123 case Operator.BitwiseAnd:
3124 opcode = OpCodes.And;
3127 case Operator.ExclusiveOr:
3128 opcode = OpCodes.Xor;
3132 throw new Exception ("This should not happen: Operator = "
3133 + oper.ToString ());
3141 // Object created by Binary when the binary operator uses an method instead of being
3142 // a binary operation that maps to a CIL binary operation.
3144 public class BinaryMethod : Expression {
3145 public MethodBase method;
3146 public ArrayList Arguments;
3148 public BinaryMethod (Type t, MethodBase m, ArrayList args)
3153 eclass = ExprClass.Value;
3156 public override Expression DoResolve (EmitContext ec)
3161 public override void Emit (EmitContext ec)
3163 ILGenerator ig = ec.ig;
3165 if (Arguments != null)
3166 Invocation.EmitArguments (ec, method, Arguments);
3168 if (method is MethodInfo)
3169 ig.Emit (OpCodes.Call, (MethodInfo) method);
3171 ig.Emit (OpCodes.Call, (ConstructorInfo) method);
3176 // Represents the operation a + b [+ c [+ d [+ ...]]], where a is a string
3177 // b, c, d... may be strings or objects.
3179 public class StringConcat : Expression {
3181 bool invalid = false;
3184 public StringConcat (EmitContext ec, Location loc, Expression left, Expression right)
3187 type = TypeManager.string_type;
3188 eclass = ExprClass.Value;
3190 operands = new ArrayList (2);
3195 public override Expression DoResolve (EmitContext ec)
3203 public void Append (EmitContext ec, Expression operand)
3208 if (operand is StringConstant && operands.Count != 0) {
3209 StringConstant last_operand = operands [operands.Count - 1] as StringConstant;
3210 if (last_operand != null) {
3211 operands [operands.Count - 1] = new StringConstant (last_operand.Value + ((StringConstant) operand).Value);
3217 // Conversion to object
3219 if (operand.Type != TypeManager.string_type) {
3220 Expression no = Convert.ImplicitConversion (ec, operand, TypeManager.object_type, loc);
3223 Binary.Error_OperatorCannotBeApplied (loc, "+", TypeManager.string_type, operand.Type);
3229 operands.Add (operand);
3232 public override void Emit (EmitContext ec)
3234 MethodInfo concat_method = null;
3237 // Are we also concating objects?
3239 bool is_strings_only = true;
3242 // Do conversion to arguments; check for strings only
3244 for (int i = 0; i < operands.Count; i ++) {
3245 Expression e = (Expression) operands [i];
3246 is_strings_only &= e.Type == TypeManager.string_type;
3249 for (int i = 0; i < operands.Count; i ++) {
3250 Expression e = (Expression) operands [i];
3252 if (! is_strings_only && e.Type == TypeManager.string_type) {
3253 // need to make sure this is an object, because the EmitParams
3254 // method might look at the type of this expression, see it is a
3255 // string and emit a string [] when we want an object [];
3257 e = Convert.ImplicitConversion (ec, e, TypeManager.object_type, loc);
3259 operands [i] = new Argument (e, Argument.AType.Expression);
3263 // Find the right method
3265 switch (operands.Count) {
3268 // This should not be possible, because simple constant folding
3269 // is taken care of in the Binary code.
3271 throw new Exception ("how did you get here?");
3274 concat_method = is_strings_only ?
3275 TypeManager.string_concat_string_string :
3276 TypeManager.string_concat_object_object ;
3279 concat_method = is_strings_only ?
3280 TypeManager.string_concat_string_string_string :
3281 TypeManager.string_concat_object_object_object ;
3285 // There is not a 4 param overlaod for object (the one that there is
3286 // is actually a varargs methods, and is only in corlib because it was
3287 // introduced there before.).
3289 if (!is_strings_only)
3292 concat_method = TypeManager.string_concat_string_string_string_string;
3295 concat_method = is_strings_only ?
3296 TypeManager.string_concat_string_dot_dot_dot :
3297 TypeManager.string_concat_object_dot_dot_dot ;
3301 Invocation.EmitArguments (ec, concat_method, operands);
3302 ec.ig.Emit (OpCodes.Call, concat_method);
3307 // Object created with +/= on delegates
3309 public class BinaryDelegate : Expression {
3313 public BinaryDelegate (Type t, MethodInfo mi, ArrayList args)
3318 eclass = ExprClass.Value;
3321 public override Expression DoResolve (EmitContext ec)
3326 public override void Emit (EmitContext ec)
3328 ILGenerator ig = ec.ig;
3330 Invocation.EmitArguments (ec, method, args);
3332 ig.Emit (OpCodes.Call, (MethodInfo) method);
3333 ig.Emit (OpCodes.Castclass, type);
3336 public Expression Right {
3338 Argument arg = (Argument) args [1];
3343 public bool IsAddition {
3345 return method == TypeManager.delegate_combine_delegate_delegate;
3351 // User-defined conditional logical operator
3352 public class ConditionalLogicalOperator : Expression {
3353 Expression left, right;
3356 public ConditionalLogicalOperator (bool is_and, Expression left, Expression right, Type t, Location loc)
3359 eclass = ExprClass.Value;
3363 this.is_and = is_and;
3366 protected void Error19 ()
3368 Binary.Error_OperatorCannotBeApplied (loc, is_and ? "&&" : "||", type, type);
3371 protected void Error218 ()
3373 Error (218, "The type ('" + TypeManager.CSharpName (type) + "') must contain " +
3374 "declarations of operator true and operator false");
3377 Expression op_true, op_false, op;
3378 LocalTemporary left_temp;
3380 public override Expression DoResolve (EmitContext ec)
3383 Expression operator_group;
3385 operator_group = MethodLookup (ec, type, is_and ? "op_BitwiseAnd" : "op_BitwiseOr", loc);
3386 if (operator_group == null) {
3391 left_temp = new LocalTemporary (ec, type);
3393 ArrayList arguments = new ArrayList ();
3394 arguments.Add (new Argument (left_temp, Argument.AType.Expression));
3395 arguments.Add (new Argument (right, Argument.AType.Expression));
3396 method = Invocation.OverloadResolve (
3397 ec, (MethodGroupExpr) operator_group, arguments, false, loc)
3399 if ((method == null) || (method.ReturnType != type)) {
3404 op = new StaticCallExpr (method, arguments, loc);
3406 op_true = GetOperatorTrue (ec, left_temp, loc);
3407 op_false = GetOperatorFalse (ec, left_temp, loc);
3408 if ((op_true == null) || (op_false == null)) {
3416 public override void Emit (EmitContext ec)
3418 ILGenerator ig = ec.ig;
3419 Label false_target = ig.DefineLabel ();
3420 Label end_target = ig.DefineLabel ();
3422 ig.Emit (OpCodes.Nop);
3425 left_temp.Store (ec);
3427 (is_and ? op_false : op_true).EmitBranchable (ec, false_target, false);
3428 left_temp.Emit (ec);
3429 ig.Emit (OpCodes.Br, end_target);
3430 ig.MarkLabel (false_target);
3432 ig.MarkLabel (end_target);
3434 ig.Emit (OpCodes.Nop);
3438 public class PointerArithmetic : Expression {
3439 Expression left, right;
3443 // We assume that `l' is always a pointer
3445 public PointerArithmetic (bool is_addition, Expression l, Expression r, Type t, Location loc)
3448 eclass = ExprClass.Variable;
3452 is_add = is_addition;
3455 public override Expression DoResolve (EmitContext ec)
3458 // We are born fully resolved
3463 public override void Emit (EmitContext ec)
3465 Type op_type = left.Type;
3466 ILGenerator ig = ec.ig;
3467 int size = GetTypeSize (TypeManager.GetElementType (op_type));
3468 Type rtype = right.Type;
3470 if (rtype.IsPointer){
3472 // handle (pointer - pointer)
3476 ig.Emit (OpCodes.Sub);
3480 ig.Emit (OpCodes.Sizeof, op_type);
3482 IntLiteral.EmitInt (ig, size);
3483 ig.Emit (OpCodes.Div);
3485 ig.Emit (OpCodes.Conv_I8);
3488 // handle + and - on (pointer op int)
3491 ig.Emit (OpCodes.Conv_I);
3495 ig.Emit (OpCodes.Sizeof, op_type);
3497 IntLiteral.EmitInt (ig, size);
3498 if (rtype == TypeManager.int64_type)
3499 ig.Emit (OpCodes.Conv_I8);
3500 else if (rtype == TypeManager.uint64_type)
3501 ig.Emit (OpCodes.Conv_U8);
3502 ig.Emit (OpCodes.Mul);
3503 ig.Emit (OpCodes.Conv_I);
3506 ig.Emit (OpCodes.Add);
3508 ig.Emit (OpCodes.Sub);
3514 /// Implements the ternary conditional operator (?:)
3516 public class Conditional : Expression {
3517 Expression expr, trueExpr, falseExpr;
3519 public Conditional (Expression expr, Expression trueExpr, Expression falseExpr, Location l)
3522 this.trueExpr = trueExpr;
3523 this.falseExpr = falseExpr;
3527 public Expression Expr {
3533 public Expression TrueExpr {
3539 public Expression FalseExpr {
3545 public override Expression DoResolve (EmitContext ec)
3547 expr = expr.Resolve (ec);
3552 if (expr.Type != TypeManager.bool_type){
3553 expr = Expression.ResolveBoolean (
3560 trueExpr = trueExpr.Resolve (ec);
3561 falseExpr = falseExpr.Resolve (ec);
3563 if (trueExpr == null || falseExpr == null)
3566 eclass = ExprClass.Value;
3567 if (trueExpr.Type == falseExpr.Type)
3568 type = trueExpr.Type;
3571 Type true_type = trueExpr.Type;
3572 Type false_type = falseExpr.Type;
3574 if (trueExpr is NullLiteral){
3577 } else if (falseExpr is NullLiteral){
3583 // First, if an implicit conversion exists from trueExpr
3584 // to falseExpr, then the result type is of type falseExpr.Type
3586 conv = Convert.ImplicitConversion (ec, trueExpr, false_type, loc);
3589 // Check if both can convert implicitl to each other's type
3591 if (Convert.ImplicitConversion (ec, falseExpr, true_type, loc) != null){
3593 "Can not compute type of conditional expression " +
3594 "as `" + TypeManager.CSharpName (trueExpr.Type) +
3595 "' and `" + TypeManager.CSharpName (falseExpr.Type) +
3596 "' convert implicitly to each other");
3601 } else if ((conv = Convert.ImplicitConversion(ec, falseExpr, true_type,loc))!= null){
3605 Error (173, "The type of the conditional expression can " +
3606 "not be computed because there is no implicit conversion" +
3607 " from `" + TypeManager.CSharpName (trueExpr.Type) + "'" +
3608 " and `" + TypeManager.CSharpName (falseExpr.Type) + "'");
3613 if (expr is BoolConstant){
3614 BoolConstant bc = (BoolConstant) expr;
3625 public override void Emit (EmitContext ec)
3627 ILGenerator ig = ec.ig;
3628 Label false_target = ig.DefineLabel ();
3629 Label end_target = ig.DefineLabel ();
3631 expr.EmitBranchable (ec, false_target, false);
3633 ig.Emit (OpCodes.Br, end_target);
3634 ig.MarkLabel (false_target);
3635 falseExpr.Emit (ec);
3636 ig.MarkLabel (end_target);
3644 public class LocalVariableReference : Expression, IAssignMethod, IMemoryLocation, IVariable {
3645 public readonly string Name;
3646 public readonly Block Block;
3647 LocalInfo local_info;
3650 public LocalVariableReference (Block block, string name, Location l)
3655 eclass = ExprClass.Variable;
3658 // Setting `is_readonly' to false will allow you to create a writable
3659 // reference to a read-only variable. This is used by foreach and using.
3660 public LocalVariableReference (Block block, string name, Location l,
3661 LocalInfo local_info, bool is_readonly)
3662 : this (block, name, l)
3664 this.local_info = local_info;
3665 this.is_readonly = is_readonly;
3668 public VariableInfo VariableInfo {
3669 get { return local_info.VariableInfo; }
3672 public bool IsReadOnly {
3678 protected void DoResolveBase (EmitContext ec)
3680 if (local_info == null) {
3681 local_info = Block.GetLocalInfo (Name);
3682 is_readonly = local_info.ReadOnly;
3685 type = local_info.VariableType;
3687 if (ec.InAnonymousMethod)
3688 Block.LiftVariable (local_info);
3692 protected Expression DoResolve (EmitContext ec, bool is_lvalue)
3694 Expression e = Block.GetConstantExpression (Name);
3696 local_info.Used = true;
3697 eclass = ExprClass.Value;
3701 VariableInfo variable_info = local_info.VariableInfo;
3702 if ((variable_info != null) && !variable_info.IsAssigned (ec, loc))
3706 local_info.Used = true;
3708 if (local_info.LocalBuilder == null)
3709 return ec.RemapLocal (local_info);
3714 public override Expression DoResolve (EmitContext ec)
3718 return DoResolve (ec, false);
3721 override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
3725 VariableInfo variable_info = local_info.VariableInfo;
3726 if (variable_info != null)
3727 variable_info.SetAssigned (ec);
3729 Expression e = DoResolve (ec, true);
3735 Error (1604, "cannot assign to `" + Name + "' because it is readonly");
3739 CheckObsoleteAttribute (e.Type);
3741 if (local_info.LocalBuilder == null)
3742 return ec.RemapLocalLValue (local_info, right_side);
3747 public bool VerifyFixed (bool is_expression)
3749 return !is_expression || local_info.IsFixed;
3752 public override void Emit (EmitContext ec)
3754 ILGenerator ig = ec.ig;
3756 ig.Emit (OpCodes.Ldloc, local_info.LocalBuilder);
3759 public void EmitAssign (EmitContext ec, Expression source)
3761 ILGenerator ig = ec.ig;
3764 ig.Emit (OpCodes.Stloc, local_info.LocalBuilder);
3767 public void AddressOf (EmitContext ec, AddressOp mode)
3769 ILGenerator ig = ec.ig;
3771 ig.Emit (OpCodes.Ldloca, local_info.LocalBuilder);
3774 public override string ToString ()
3776 return String.Format ("{0} ({1}:{2})", GetType (), Name, loc);
3781 /// This represents a reference to a parameter in the intermediate
3784 public class ParameterReference : Expression, IAssignMethod, IMemoryLocation, IVariable {
3790 public Parameter.Modifier mod;
3791 public bool is_ref, is_out;
3793 public ParameterReference (Parameters pars, Block block, int idx, string name, Location loc)
3800 eclass = ExprClass.Variable;
3803 public VariableInfo VariableInfo {
3807 public bool VerifyFixed (bool is_expression)
3809 return !is_expression || TypeManager.IsValueType (type);
3812 public bool IsAssigned (EmitContext ec, Location loc)
3814 if (!ec.DoFlowAnalysis || !is_out ||
3815 ec.CurrentBranching.IsAssigned (vi))
3818 Report.Error (165, loc,
3819 "Use of unassigned parameter `" + name + "'");
3823 public bool IsFieldAssigned (EmitContext ec, string field_name, Location loc)
3825 if (!ec.DoFlowAnalysis || !is_out ||
3826 ec.CurrentBranching.IsFieldAssigned (vi, field_name))
3829 Report.Error (170, loc,
3830 "Use of possibly unassigned field `" + field_name + "'");
3834 public void SetAssigned (EmitContext ec)
3836 if (is_out && ec.DoFlowAnalysis)
3837 ec.CurrentBranching.SetAssigned (vi);
3840 public void SetFieldAssigned (EmitContext ec, string field_name)
3842 if (is_out && ec.DoFlowAnalysis)
3843 ec.CurrentBranching.SetFieldAssigned (vi, field_name);
3846 protected void DoResolveBase (EmitContext ec)
3848 type = pars.GetParameterInfo (ec.DeclSpace, idx, out mod);
3849 is_ref = (mod & Parameter.Modifier.ISBYREF) != 0;
3850 is_out = (mod & Parameter.Modifier.OUT) != 0;
3851 eclass = ExprClass.Variable;
3854 vi = block.ParameterMap [idx];
3858 // Notice that for ref/out parameters, the type exposed is not the
3859 // same type exposed externally.
3862 // externally we expose "int&"
3863 // here we expose "int".
3865 // We record this in "is_ref". This means that the type system can treat
3866 // the type as it is expected, but when we generate the code, we generate
3867 // the alternate kind of code.
3869 public override Expression DoResolve (EmitContext ec)
3873 if (is_out && ec.DoFlowAnalysis && !IsAssigned (ec, loc))
3876 if (ec.RemapToProxy)
3877 return ec.RemapParameter (idx);
3882 override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
3888 if (ec.RemapToProxy)
3889 return ec.RemapParameterLValue (idx, right_side);
3894 static public void EmitLdArg (ILGenerator ig, int x)
3898 case 0: ig.Emit (OpCodes.Ldarg_0); break;
3899 case 1: ig.Emit (OpCodes.Ldarg_1); break;
3900 case 2: ig.Emit (OpCodes.Ldarg_2); break;
3901 case 3: ig.Emit (OpCodes.Ldarg_3); break;
3902 default: ig.Emit (OpCodes.Ldarg_S, (byte) x); break;
3905 ig.Emit (OpCodes.Ldarg, x);
3909 // This method is used by parameters that are references, that are
3910 // being passed as references: we only want to pass the pointer (that
3911 // is already stored in the parameter, not the address of the pointer,
3912 // and not the value of the variable).
3914 public void EmitLoad (EmitContext ec)
3916 ILGenerator ig = ec.ig;
3922 EmitLdArg (ig, arg_idx);
3925 public override void Emit (EmitContext ec)
3927 ILGenerator ig = ec.ig;
3934 EmitLdArg (ig, arg_idx);
3940 // If we are a reference, we loaded on the stack a pointer
3941 // Now lets load the real value
3943 LoadFromPtr (ig, type);
3946 public void EmitAssign (EmitContext ec, Expression source)
3948 ILGenerator ig = ec.ig;
3956 EmitLdArg (ig, arg_idx);
3961 StoreFromPtr (ig, type);
3964 ig.Emit (OpCodes.Starg_S, (byte) arg_idx);
3966 ig.Emit (OpCodes.Starg, arg_idx);
3970 public void AddressOf (EmitContext ec, AddressOp mode)
3979 ec.ig.Emit (OpCodes.Ldarg_S, (byte) arg_idx);
3981 ec.ig.Emit (OpCodes.Ldarg, arg_idx);
3984 ec.ig.Emit (OpCodes.Ldarga_S, (byte) arg_idx);
3986 ec.ig.Emit (OpCodes.Ldarga, arg_idx);
3993 /// Used for arguments to New(), Invocation()
3995 public class Argument {
3996 public enum AType : byte {
4002 public readonly AType ArgType;
4003 public Expression Expr;
4005 public Argument (Expression expr, AType type)
4008 this.ArgType = type;
4013 if (ArgType == AType.Ref || ArgType == AType.Out)
4014 return TypeManager.GetReferenceType (Expr.Type);
4020 public Parameter.Modifier GetParameterModifier ()
4024 return Parameter.Modifier.OUT | Parameter.Modifier.ISBYREF;
4027 return Parameter.Modifier.REF | Parameter.Modifier.ISBYREF;
4030 return Parameter.Modifier.NONE;
4034 public static string FullDesc (Argument a)
4036 return (a.ArgType == AType.Ref ? "ref " :
4037 (a.ArgType == AType.Out ? "out " : "")) +
4038 TypeManager.CSharpName (a.Expr.Type);
4041 public bool ResolveMethodGroup (EmitContext ec, Location loc)
4043 ConstructedType ctype = Expr as ConstructedType;
4045 Expr = ctype.GetSimpleName (ec);
4047 // FIXME: csc doesn't report any error if you try to use `ref' or
4048 // `out' in a delegate creation expression.
4049 Expr = Expr.Resolve (ec, ResolveFlags.VariableOrValue | ResolveFlags.MethodGroup);
4056 public bool Resolve (EmitContext ec, Location loc)
4058 if (ArgType == AType.Ref) {
4059 Expr = Expr.Resolve (ec);
4063 Expr = Expr.ResolveLValue (ec, Expr);
4064 } else if (ArgType == AType.Out)
4065 Expr = Expr.ResolveLValue (ec, new EmptyExpression ());
4067 Expr = Expr.Resolve (ec);
4072 if (ArgType == AType.Expression)
4076 // Catch errors where fields of a MarshalByRefObject are passed as ref or out
4077 // This is only allowed for `this'
4079 FieldExpr fe = Expr as FieldExpr;
4080 if (fe != null && !fe.IsStatic){
4081 Expression instance = fe.InstanceExpression;
4083 if (instance.GetType () != typeof (This)){
4084 if (fe.InstanceExpression.Type.IsSubclassOf (TypeManager.mbr_type)){
4085 Report.Error (197, loc,
4086 "Can not pass a type that derives from MarshalByRefObject with out or ref");
4093 if (Expr.eclass != ExprClass.Variable){
4095 // We just probe to match the CSC output
4097 if (Expr.eclass == ExprClass.PropertyAccess ||
4098 Expr.eclass == ExprClass.IndexerAccess){
4101 "A property or indexer can not be passed as an out or ref " +
4106 "An lvalue is required as an argument to out or ref");
4114 public void Emit (EmitContext ec)
4117 // Ref and Out parameters need to have their addresses taken.
4119 // ParameterReferences might already be references, so we want
4120 // to pass just the value
4122 if (ArgType == AType.Ref || ArgType == AType.Out){
4123 AddressOp mode = AddressOp.Store;
4125 if (ArgType == AType.Ref)
4126 mode |= AddressOp.Load;
4128 if (Expr is ParameterReference){
4129 ParameterReference pr = (ParameterReference) Expr;
4135 pr.AddressOf (ec, mode);
4138 ((IMemoryLocation)Expr).AddressOf (ec, mode);
4146 /// Invocation of methods or delegates.
4148 public class Invocation : ExpressionStatement {
4149 public readonly ArrayList Arguments;
4152 MethodBase method = null;
4155 static Hashtable method_parameter_cache;
4157 static Invocation ()
4159 method_parameter_cache = new PtrHashtable ();
4163 // arguments is an ArrayList, but we do not want to typecast,
4164 // as it might be null.
4166 // FIXME: only allow expr to be a method invocation or a
4167 // delegate invocation (7.5.5)
4169 public Invocation (Expression expr, ArrayList arguments, Location l)
4172 Arguments = arguments;
4176 public Expression Expr {
4183 /// Returns the Parameters (a ParameterData interface) for the
4186 public static ParameterData GetParameterData (MethodBase mb)
4188 object pd = method_parameter_cache [mb];
4192 return (ParameterData) pd;
4194 ip = TypeManager.LookupParametersByBuilder (mb);
4196 method_parameter_cache [mb] = ip;
4198 return (ParameterData) ip;
4200 ReflectionParameters rp = new ReflectionParameters (mb);
4201 method_parameter_cache [mb] = rp;
4203 return (ParameterData) rp;
4208 /// Determines "better conversion" as specified in 7.4.2.3
4210 /// Returns : 1 if a->p is better
4211 /// 0 if a->q or neither is better
4213 static int BetterConversion (EmitContext ec, Argument a, Type p, Type q, Location loc)
4215 Type argument_type = a.Type;
4216 Expression argument_expr = a.Expr;
4218 if (argument_type == null)
4219 throw new Exception ("Expression of type " + a.Expr +
4220 " does not resolve its type");
4223 // This is a special case since csc behaves this way.
4225 if (argument_expr is NullLiteral &&
4226 p == TypeManager.string_type &&
4227 q == TypeManager.object_type)
4229 else if (argument_expr is NullLiteral &&
4230 p == TypeManager.object_type &&
4231 q == TypeManager.string_type)
4235 // csc behaves this way so we emulate it. Basically, if the argument
4236 // is null and one of the types to compare is 'object' and the other
4237 // is a reference type, we prefer the other.
4239 // I can't find this anywhere in the spec but we can interpret this
4240 // to mean that null can be of any type you wish in such a context
4242 if (p != null && q != null) {
4243 if (argument_expr is NullLiteral &&
4245 q == TypeManager.object_type)
4247 else if (argument_expr is NullLiteral &&
4249 p == TypeManager.object_type)
4256 if (argument_type == p)
4259 if (argument_type == q)
4263 // Now probe whether an implicit constant expression conversion
4266 // An implicit constant expression conversion permits the following
4269 // * A constant-expression of type `int' can be converted to type
4270 // sbyte, byute, short, ushort, uint, ulong provided the value of
4271 // of the expression is withing the range of the destination type.
4273 // * A constant-expression of type long can be converted to type
4274 // ulong, provided the value of the constant expression is not negative
4276 // FIXME: Note that this assumes that constant folding has
4277 // taken place. We dont do constant folding yet.
4280 if (argument_expr is IntConstant){
4281 IntConstant ei = (IntConstant) argument_expr;
4282 int value = ei.Value;
4284 if (p == TypeManager.sbyte_type){
4285 if (value >= SByte.MinValue && value <= SByte.MaxValue)
4287 } else if (p == TypeManager.byte_type){
4288 if (q == TypeManager.sbyte_type &&
4289 value >= SByte.MinValue && value <= SByte.MaxValue)
4291 else if (Byte.MinValue >= 0 && value <= Byte.MaxValue)
4293 } else if (p == TypeManager.short_type){
4294 if (value >= Int16.MinValue && value <= Int16.MaxValue)
4296 } else if (p == TypeManager.ushort_type){
4297 if (q == TypeManager.short_type &&
4298 value >= Int16.MinValue && value <= Int16.MaxValue)
4300 else if (value >= UInt16.MinValue && value <= UInt16.MaxValue)
4302 } else if (p == TypeManager.int32_type){
4303 if (value >= Int32.MinValue && value <= Int32.MaxValue)
4305 } else if (p == TypeManager.uint32_type){
4307 // we can optimize this case: a positive int32
4308 // always fits on a uint32
4312 } else if (p == TypeManager.uint64_type){
4314 // we can optimize this case: a positive int32
4315 // always fits on a uint64
4319 // This special case is needed because csc behaves like this.
4320 // int -> uint is better than int -> ulong!
4322 if (q == TypeManager.uint32_type)
4325 if (q == TypeManager.int64_type)
4327 else if (value >= 0)
4329 } else if (p == TypeManager.int64_type){
4332 } else if (argument_type == TypeManager.int64_type && argument_expr is LongConstant){
4333 LongConstant lc = (LongConstant) argument_expr;
4335 if (p == TypeManager.uint64_type){
4342 Expression tmp = Convert.ImplicitConversion (ec, argument_expr, p, loc);
4350 Expression p_tmp = new EmptyExpression (p);
4351 Expression q_tmp = new EmptyExpression (q);
4353 if (Convert.ImplicitConversionExists (ec, p_tmp, q) == true &&
4354 Convert.ImplicitConversionExists (ec, q_tmp, p) == false)
4357 if (p == TypeManager.sbyte_type)
4358 if (q == TypeManager.byte_type || q == TypeManager.ushort_type ||
4359 q == TypeManager.uint32_type || q == TypeManager.uint64_type)
4362 if (p == TypeManager.short_type)
4363 if (q == TypeManager.ushort_type || q == TypeManager.uint32_type ||
4364 q == TypeManager.uint64_type)
4367 if (p == TypeManager.int32_type)
4368 if (q == TypeManager.uint32_type || q == TypeManager.uint64_type)
4371 if (p == TypeManager.int64_type)
4372 if (q == TypeManager.uint64_type)
4379 /// Determines "Better function" between candidate
4380 /// and the current best match
4383 /// Returns an integer indicating :
4384 /// 0 if candidate ain't better
4385 /// 1 if candidate is better than the current best match
4387 static int BetterFunction (EmitContext ec, ArrayList args,
4388 MethodBase candidate, bool candidate_params,
4389 MethodBase best, bool best_params,
4392 ParameterData candidate_pd = GetParameterData (candidate);
4393 ParameterData best_pd;
4399 argument_count = args.Count;
4401 int cand_count = candidate_pd.Count;
4404 // If there is no best method, than this one
4405 // is better, however, if we already found a
4406 // best method, we cant tell. This happens
4417 // interface IFooBar : IFoo, IBar {}
4419 // We cant tell if IFoo.DoIt is better than IBar.DoIt
4421 // However, we have to consider that
4422 // Trim (); is better than Trim (params char[] chars);
4424 if (cand_count == 0 && argument_count == 0)
4425 return best == null || best_params ? 1 : 0;
4427 if (candidate_pd.ParameterModifier (cand_count - 1) != Parameter.Modifier.PARAMS)
4428 if (cand_count != argument_count)
4434 if (argument_count == 0 && cand_count == 1 &&
4435 candidate_pd.ParameterModifier (cand_count - 1) == Parameter.Modifier.PARAMS)
4438 for (int j = 0; j < argument_count; ++j) {
4440 Argument a = (Argument) args [j];
4441 Type t = candidate_pd.ParameterType (j);
4443 if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
4444 if (candidate_params)
4445 t = TypeManager.GetElementType (t);
4447 x = BetterConversion (ec, a, t, null, loc);
4459 best_pd = GetParameterData (best);
4461 int rating1 = 0, rating2 = 0;
4463 for (int j = 0; j < argument_count; ++j) {
4466 Argument a = (Argument) args [j];
4468 Type ct = candidate_pd.ParameterType (j);
4469 Type bt = best_pd.ParameterType (j);
4471 if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
4472 if (candidate_params)
4473 ct = TypeManager.GetElementType (ct);
4475 if (best_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
4477 bt = TypeManager.GetElementType (bt);
4479 x = BetterConversion (ec, a, ct, bt, loc);
4480 y = BetterConversion (ec, a, bt, ct, loc);
4490 // If a method (in the normal form) with the
4491 // same signature as the expanded form of the
4492 // current best params method already exists,
4493 // the expanded form is not applicable so we
4494 // force it to select the candidate
4496 if (!candidate_params && best_params && cand_count == argument_count)
4499 if (rating1 > rating2)
4505 public static string FullMethodDesc (MethodBase mb)
4507 string ret_type = "";
4512 if (mb is MethodInfo)
4513 ret_type = TypeManager.CSharpName (((MethodInfo) mb).ReturnType);
4515 StringBuilder sb = new StringBuilder (ret_type);
4517 sb.Append (mb.ReflectedType.ToString ());
4519 sb.Append (mb.Name);
4521 ParameterData pd = GetParameterData (mb);
4523 int count = pd.Count;
4526 for (int i = count; i > 0; ) {
4529 sb.Append (pd.ParameterDesc (count - i - 1));
4535 return sb.ToString ();
4538 public static MethodGroupExpr MakeUnionSet (Expression mg1, Expression mg2, Location loc)
4540 MemberInfo [] miset;
4541 MethodGroupExpr union;
4546 return (MethodGroupExpr) mg2;
4549 return (MethodGroupExpr) mg1;
4552 MethodGroupExpr left_set = null, right_set = null;
4553 int length1 = 0, length2 = 0;
4555 left_set = (MethodGroupExpr) mg1;
4556 length1 = left_set.Methods.Length;
4558 right_set = (MethodGroupExpr) mg2;
4559 length2 = right_set.Methods.Length;
4561 ArrayList common = new ArrayList ();
4563 foreach (MethodBase r in right_set.Methods){
4564 if (TypeManager.ArrayContainsMethod (left_set.Methods, r))
4568 miset = new MemberInfo [length1 + length2 - common.Count];
4569 left_set.Methods.CopyTo (miset, 0);
4573 foreach (MethodBase r in right_set.Methods) {
4574 if (!common.Contains (r))
4578 union = new MethodGroupExpr (miset, loc);
4583 static bool IsParamsMethodApplicable (EmitContext ec, MethodGroupExpr me,
4584 ArrayList arguments, ref MethodBase candidate)
4586 if (!me.HasTypeArguments &&
4587 !InferParamsTypeArguments (ec, arguments, ref candidate))
4590 return IsParamsMethodApplicable (ec, arguments, candidate);
4594 /// Determines if the candidate method, if a params method, is applicable
4595 /// in its expanded form to the given set of arguments
4597 static bool IsParamsMethodApplicable (EmitContext ec, ArrayList arguments, MethodBase candidate)
4601 if (arguments == null)
4604 arg_count = arguments.Count;
4606 ParameterData pd = GetParameterData (candidate);
4608 int pd_count = pd.Count;
4613 if (pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS)
4616 if (pd_count - 1 > arg_count)
4619 if (pd_count == 1 && arg_count == 0)
4623 // If we have come this far, the case which
4624 // remains is when the number of parameters is
4625 // less than or equal to the argument count.
4627 for (int i = 0; i < pd_count - 1; ++i) {
4629 Argument a = (Argument) arguments [i];
4631 Parameter.Modifier a_mod = a.GetParameterModifier () &
4632 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
4633 Parameter.Modifier p_mod = pd.ParameterModifier (i) &
4634 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
4636 if (a_mod == p_mod) {
4638 if (a_mod == Parameter.Modifier.NONE)
4639 if (!Convert.ImplicitConversionExists (ec,
4641 pd.ParameterType (i)))
4644 if ((a_mod & Parameter.Modifier.ISBYREF) != 0) {
4645 Type pt = pd.ParameterType (i);
4648 pt = TypeManager.GetReferenceType (pt);
4658 Type element_type = TypeManager.GetElementType (pd.ParameterType (pd_count - 1));
4660 for (int i = pd_count - 1; i < arg_count; i++) {
4661 Argument a = (Argument) arguments [i];
4663 if (!Convert.ImplicitConversionExists (ec, a.Expr, element_type))
4670 static bool IsApplicable (EmitContext ec, MethodGroupExpr me,
4671 ArrayList arguments, ref MethodBase candidate)
4673 if (!me.HasTypeArguments &&
4674 !InferTypeArguments (ec, arguments, ref candidate))
4677 return IsApplicable (ec, arguments, candidate);
4681 /// Determines if the candidate method is applicable (section 14.4.2.1)
4682 /// to the given set of arguments
4684 static bool IsApplicable (EmitContext ec, ArrayList arguments, MethodBase candidate)
4688 if (arguments == null)
4691 arg_count = arguments.Count;
4694 ParameterData pd = GetParameterData (candidate);
4696 if (arg_count != pd.Count)
4699 for (int i = arg_count; i > 0; ) {
4702 Argument a = (Argument) arguments [i];
4704 Parameter.Modifier a_mod = a.GetParameterModifier () &
4705 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
4706 Parameter.Modifier p_mod = pd.ParameterModifier (i) &
4707 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
4710 if (a_mod == p_mod ||
4711 (a_mod == Parameter.Modifier.NONE && p_mod == Parameter.Modifier.PARAMS)) {
4712 if (a_mod == Parameter.Modifier.NONE) {
4713 if (!Convert.ImplicitConversionExists (ec,
4715 pd.ParameterType (i)))
4719 if ((a_mod & Parameter.Modifier.ISBYREF) != 0) {
4720 Type pt = pd.ParameterType (i);
4723 pt = TypeManager.GetReferenceType (pt);
4736 /// Find the Applicable Function Members (7.4.2.1)
4738 /// me: Method Group expression with the members to select.
4739 /// it might contain constructors or methods (or anything
4740 /// that maps to a method).
4742 /// Arguments: ArrayList containing resolved Argument objects.
4744 /// loc: The location if we want an error to be reported, or a Null
4745 /// location for "probing" purposes.
4747 /// Returns: The MethodBase (either a ConstructorInfo or a MethodInfo)
4748 /// that is the best match of me on Arguments.
4751 public static MethodBase OverloadResolve (EmitContext ec, MethodGroupExpr me,
4752 ArrayList Arguments, bool may_fail,
4755 MethodBase method = null;
4756 Type applicable_type = null;
4758 ArrayList candidates = new ArrayList ();
4761 // Used to keep a map between the candidate
4762 // and whether it is being considered in its
4763 // normal or expanded form
4765 // false is normal form, true is expanded form
4767 Hashtable candidate_to_form = new PtrHashtable ();
4771 // First we construct the set of applicable methods
4773 // We start at the top of the type hierarchy and
4774 // go down to find applicable methods
4776 applicable_type = me.DeclaringType;
4778 if (me.Name == "Invoke" && TypeManager.IsDelegateType (applicable_type)) {
4779 Error_InvokeOnDelegate (loc);
4783 bool found_applicable = false;
4785 MethodBase[] methods = me.Methods;
4787 for (int i = 0; i < methods.Length; i++) {
4788 Type decl_type = methods [i].DeclaringType;
4791 // If we have already found an applicable method
4792 // we eliminate all base types (Section 14.5.5.1)
4794 if (decl_type != applicable_type &&
4795 (applicable_type.IsSubclassOf (decl_type) ||
4796 TypeManager.ImplementsInterface (applicable_type, decl_type)) &&
4800 // Check if candidate is applicable (section 14.4.2.1)
4801 if (IsApplicable (ec, me, Arguments, ref methods [i])) {
4802 // Candidate is applicable in normal form
4803 MethodBase candidate = methods [i];
4804 candidates.Add (candidate);
4805 applicable_type = candidate.DeclaringType;
4806 found_applicable = true;
4807 candidate_to_form [candidate] = false;
4808 } else if (IsParamsMethodApplicable (ec, me, Arguments, ref methods [i])) {
4809 // Candidate is applicable in expanded form
4810 MethodBase candidate = methods [i];
4811 candidates.Add (candidate);
4812 applicable_type = candidate.DeclaringType;
4813 found_applicable = true;
4814 candidate_to_form [candidate] = true;
4818 if (Arguments == null)
4821 argument_count = Arguments.Count;
4824 // Now we actually find the best method
4826 int candidate_top = candidates.Count;
4827 for (int ix = 0; ix < candidate_top; ix++){
4828 MethodBase candidate = (MethodBase) candidates [ix];
4830 bool cand_params = (bool) candidate_to_form [candidate];
4831 bool method_params = false;
4834 method_params = (bool) candidate_to_form [method];
4836 int x = BetterFunction (ec, Arguments,
4837 candidate, cand_params,
4838 method, method_params,
4846 if (method == null) {
4847 int errors = Report.Errors;
4850 // Okay so we have failed to find anything so we
4851 // return by providing info about the closest match
4853 for (int i = 0; i < methods.Length; ++i) {
4855 MethodBase c = methods [i];
4859 ParameterData pd = GetParameterData (c);
4860 if (pd.Count != argument_count)
4863 if (!InferTypeArguments (ec, Arguments, ref c))
4866 VerifyArgumentsCompat (ec, Arguments, argument_count,
4867 c, false, null, loc);
4871 if (Report.Errors > errors)
4874 string report_name = me.Name;
4875 if (report_name == ".ctor")
4876 report_name = me.DeclaringType.ToString ();
4878 for (int i = 0; i < methods.Length; ++i) {
4880 MethodBase c = methods [i];
4884 ParameterData pd = GetParameterData (c);
4885 if (pd.Count != argument_count)
4888 if (InferTypeArguments (ec, Arguments, ref c))
4891 Report.Error (411, loc, "The type arguments for " +
4892 "method `{0}' cannot be infered from " +
4893 "the usage. Try specifying the type " +
4894 "arguments explicitly.", report_name);
4898 if (!may_fail && (errors == Report.Errors))
4899 Error_WrongNumArguments (loc, report_name,
4906 // Now check that there are no ambiguities i.e the selected method
4907 // should be better than all the others
4909 bool best_params = (bool) candidate_to_form [method];
4911 for (int ix = 0; ix < candidate_top; ix++){
4912 MethodBase candidate = (MethodBase) candidates [ix];
4914 if (candidate == method)
4918 // If a normal method is applicable in
4919 // the sense that it has the same
4920 // number of arguments, then the
4921 // expanded params method is never
4922 // applicable so we debar the params
4925 // if ((IsParamsMethodApplicable (ec, Arguments, candidate) &&
4926 // IsApplicable (ec, Arguments, method)))
4929 bool cand_params = (bool) candidate_to_form [candidate];
4930 int x = BetterFunction (ec, Arguments,
4931 method, best_params,
4932 candidate, cand_params,
4938 "Ambiguous call when selecting function due to implicit casts");
4944 // And now check if the arguments are all
4945 // compatible, perform conversions if
4946 // necessary etc. and return if everything is
4949 if (!VerifyArgumentsCompat (ec, Arguments, argument_count, method,
4950 best_params, null, loc))
4956 static void Error_WrongNumArguments (Location loc, String name, int arg_count)
4958 Report.Error (1501, loc,
4959 "No overload for method `" + name + "' takes `" +
4960 arg_count + "' arguments");
4963 static void Error_InvokeOnDelegate (Location loc)
4965 Report.Error (1533, loc,
4966 "Invoke cannot be called directly on a delegate");
4969 static void Error_InvalidArguments (Location loc, int idx, MethodBase method,
4970 Type delegate_type, string arg_sig, string par_desc)
4972 if (delegate_type == null)
4973 Report.Error (1502, loc,
4974 "The best overloaded match for method '" +
4975 FullMethodDesc (method) +
4976 "' has some invalid arguments");
4978 Report.Error (1594, loc,
4979 "Delegate '" + delegate_type.ToString () +
4980 "' has some invalid arguments.");
4981 Report.Error (1503, loc,
4982 String.Format ("Argument {0}: Cannot convert from '{1}' to '{2}'",
4983 idx, arg_sig, par_desc));
4986 public static bool VerifyArgumentsCompat (EmitContext ec, ArrayList Arguments,
4989 bool chose_params_expanded,
4993 ParameterData pd = GetParameterData (method);
4994 int pd_count = pd.Count;
4996 for (int j = 0; j < argument_count; j++) {
4997 Argument a = (Argument) Arguments [j];
4998 Expression a_expr = a.Expr;
4999 Type parameter_type = pd.ParameterType (j);
5000 Parameter.Modifier pm = pd.ParameterModifier (j);
5002 if (pm == Parameter.Modifier.PARAMS){
5003 if ((pm & ~Parameter.Modifier.PARAMS) != a.GetParameterModifier ()) {
5004 if (!Location.IsNull (loc))
5005 Error_InvalidArguments (
5006 loc, j, method, delegate_type,
5007 Argument.FullDesc (a), pd.ParameterDesc (j));
5011 if (chose_params_expanded)
5012 parameter_type = TypeManager.GetElementType (parameter_type);
5017 if (pd.ParameterModifier (j) != a.GetParameterModifier ()){
5018 if (!Location.IsNull (loc))
5019 Error_InvalidArguments (
5020 loc, j, method, delegate_type,
5021 Argument.FullDesc (a), pd.ParameterDesc (j));
5029 if (a.Type != parameter_type){
5032 conv = Convert.ImplicitConversion (ec, a_expr, parameter_type, loc);
5035 if (!Location.IsNull (loc))
5036 Error_InvalidArguments (
5037 loc, j, method, delegate_type,
5038 Argument.FullDesc (a), pd.ParameterDesc (j));
5043 // Update the argument with the implicit conversion
5049 Parameter.Modifier a_mod = a.GetParameterModifier () &
5050 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
5051 Parameter.Modifier p_mod = pd.ParameterModifier (j) &
5052 ~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
5054 if (a_mod != p_mod &&
5055 pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS) {
5056 if (!Location.IsNull (loc)) {
5057 Report.Error (1502, loc,
5058 "The best overloaded match for method '" + FullMethodDesc (method)+
5059 "' has some invalid arguments");
5060 Report.Error (1503, loc,
5061 "Argument " + (j+1) +
5062 ": Cannot convert from '" + Argument.FullDesc (a)
5063 + "' to '" + pd.ParameterDesc (j) + "'");
5073 static bool InferType (Type pt, Type at, ref Type[] infered)
5075 if (pt.IsGenericParameter) {
5076 int pos = pt.GenericParameterPosition;
5078 if (infered [pos] == null) {
5080 while (check.IsArray)
5081 check = check.GetElementType ();
5083 if (pt.Equals (check))
5090 if (infered [pos] != at)
5096 if (!pt.ContainsGenericParameters)
5101 (at.GetArrayRank () != pt.GetArrayRank ()))
5104 return InferType (pt.GetElementType (), at.GetElementType (),
5110 (pt.GetArrayRank () != at.GetArrayRank ()))
5113 return InferType (pt.GetElementType (), at.GetElementType (),
5117 if (!at.IsGenericInstance)
5120 Type[] at_args = at.GetGenericArguments ();
5121 Type[] pt_args = pt.GetGenericArguments ();
5123 if (at_args.Length != pt_args.Length)
5126 Type[] infered_types = new Type [at_args.Length];
5128 for (int i = 0; i < at_args.Length; i++)
5129 if (!InferType (pt_args [i], at_args [i], ref infered_types))
5132 for (int i = 0; i < infered_types.Length; i++)
5133 if (infered_types [i] == null)
5136 for (int i = 0; i < infered_types.Length; i++) {
5137 if (infered [i] == null) {
5138 infered [i] = infered_types [i];
5142 if (infered [i] != infered_types [i])
5149 static bool InferParamsTypeArguments (EmitContext ec, ArrayList arguments,
5150 ref MethodBase method)
5152 if ((arguments == null) || !TypeManager.IsGenericMethod (method))
5157 if (arguments == null)
5160 arg_count = arguments.Count;
5162 ParameterData pd = GetParameterData (method);
5164 int pd_count = pd.Count;
5169 if (pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS)
5172 if (pd_count - 1 > arg_count)
5175 if (pd_count == 1 && arg_count == 0)
5178 Type[] method_args = method.GetGenericArguments ();
5179 Type[] infered_types = new Type [method_args.Length];
5182 // If we have come this far, the case which
5183 // remains is when the number of parameters is
5184 // less than or equal to the argument count.
5186 for (int i = 0; i < pd_count - 1; ++i) {
5187 Argument a = (Argument) arguments [i];
5189 if ((a.Expr is NullLiteral) || (a.Expr is MethodGroupExpr))
5192 Type pt = pd.ParameterType (i);
5195 if (!InferType (pt, at, ref infered_types))
5199 Type element_type = TypeManager.GetElementType (pd.ParameterType (pd_count - 1));
5201 for (int i = pd_count - 1; i < arg_count; i++) {
5202 Argument a = (Argument) arguments [i];
5204 if ((a.Expr is NullLiteral) || (a.Expr is MethodGroupExpr))
5207 if (!InferType (element_type, a.Type, ref infered_types))
5211 for (int i = 0; i < infered_types.Length; i++)
5212 if (infered_types [i] == null)
5215 method = method.BindGenericParameters (infered_types);
5219 public static bool InferTypeArguments (Type[] param_types, Type[] arg_types,
5220 ref Type[] infered_types)
5222 for (int i = 0; i < arg_types.Length; i++) {
5223 if (arg_types [i] == null)
5226 if (!InferType (param_types [i], arg_types [i],
5231 for (int i = 0; i < infered_types.Length; i++)
5232 if (infered_types [i] == null)
5238 static bool InferTypeArguments (EmitContext ec, ArrayList arguments,
5239 ref MethodBase method)
5241 if (!TypeManager.IsGenericMethod (method))
5245 if (arguments != null)
5246 arg_count = arguments.Count;
5250 ParameterData pd = GetParameterData (method);
5251 if (arg_count != pd.Count)
5254 Type[] method_args = method.GetGenericArguments ();
5255 Type[] infered_types = new Type [method_args.Length];
5257 Type[] param_types = new Type [pd.Count];
5258 Type[] arg_types = new Type [pd.Count];
5260 for (int i = 0; i < arg_count; i++) {
5261 param_types [i] = pd.ParameterType (i);
5263 Argument a = (Argument) arguments [i];
5264 if ((a.Expr is NullLiteral) || (a.Expr is MethodGroupExpr))
5267 arg_types [i] = a.Type;
5270 if (!InferTypeArguments (param_types, arg_types, ref infered_types))
5273 method = method.BindGenericParameters (infered_types);
5277 public static bool InferTypeArguments (EmitContext ec, ParameterData apd,
5278 ref MethodBase method)
5280 if (!TypeManager.IsGenericMethod (method))
5283 ParameterData pd = GetParameterData (method);
5284 if (apd.Count != pd.Count)
5287 Type[] method_args = method.GetGenericArguments ();
5288 Type[] infered_types = new Type [method_args.Length];
5290 Type[] param_types = new Type [pd.Count];
5291 Type[] arg_types = new Type [pd.Count];
5293 for (int i = 0; i < apd.Count; i++) {
5294 param_types [i] = pd.ParameterType (i);
5295 arg_types [i] = apd.ParameterType (i);
5298 if (!InferTypeArguments (param_types, arg_types, ref infered_types))
5301 method = method.BindGenericParameters (infered_types);
5305 public override Expression DoResolve (EmitContext ec)
5308 // First, resolve the expression that is used to
5309 // trigger the invocation
5311 if (expr is BaseAccess)
5314 if (expr is ConstructedType)
5315 expr = ((ConstructedType) expr).GetSimpleName (ec);
5317 expr = expr.Resolve (ec, ResolveFlags.VariableOrValue | ResolveFlags.MethodGroup);
5321 if (!(expr is MethodGroupExpr)) {
5322 Type expr_type = expr.Type;
5324 if (expr_type != null){
5325 bool IsDelegate = TypeManager.IsDelegateType (expr_type);
5327 return (new DelegateInvocation (
5328 this.expr, Arguments, loc)).Resolve (ec);
5332 if (!(expr is MethodGroupExpr)){
5333 expr.Error_UnexpectedKind (ResolveFlags.MethodGroup);
5338 // Next, evaluate all the expressions in the argument list
5340 if (Arguments != null){
5341 foreach (Argument a in Arguments){
5342 if (!a.Resolve (ec, loc))
5347 MethodGroupExpr mg = (MethodGroupExpr) expr;
5348 method = OverloadResolve (ec, mg, Arguments, false, loc);
5353 MethodInfo mi = method as MethodInfo;
5355 type = TypeManager.TypeToCoreType (mi.ReturnType);
5356 if (!mi.IsStatic && !mg.IsExplicitImpl && (mg.InstanceExpression == null)) {
5357 SimpleName.Error_ObjectRefRequired (ec, loc, mi.Name);
5361 Expression iexpr = mg.InstanceExpression;
5362 if (mi.IsStatic && (iexpr != null) && !(iexpr is This)) {
5363 if (mg.IdenticalTypeName)
5364 mg.InstanceExpression = null;
5366 MemberAccess.error176 (loc, mi.Name);
5372 if (type.IsPointer){
5380 // Only base will allow this invocation to happen.
5382 if (is_base && method.IsAbstract){
5383 Report.Error (205, loc, "Cannot call an abstract base member: " +
5384 FullMethodDesc (method));
5388 if ((method.Attributes & MethodAttributes.SpecialName) != 0){
5389 if (TypeManager.IsSpecialMethod (method))
5390 Report.Error (571, loc, method.Name + ": can not call operator or accessor");
5393 eclass = ExprClass.Value;
5398 // Emits the list of arguments as an array
5400 static void EmitParams (EmitContext ec, int idx, ArrayList arguments)
5402 ILGenerator ig = ec.ig;
5403 int count = arguments.Count - idx;
5404 Argument a = (Argument) arguments [idx];
5405 Type t = a.Expr.Type;
5407 IntConstant.EmitInt (ig, count);
5408 ig.Emit (OpCodes.Newarr, TypeManager.TypeToCoreType (t));
5410 int top = arguments.Count;
5411 for (int j = idx; j < top; j++){
5412 a = (Argument) arguments [j];
5414 ig.Emit (OpCodes.Dup);
5415 IntConstant.EmitInt (ig, j - idx);
5417 bool is_stobj, has_type_arg;
5418 OpCode op = ArrayAccess.GetStoreOpcode (t, out is_stobj, out has_type_arg);
5420 ig.Emit (OpCodes.Ldelema, t);
5432 /// Emits a list of resolved Arguments that are in the arguments
5435 /// The MethodBase argument might be null if the
5436 /// emission of the arguments is known not to contain
5437 /// a `params' field (for example in constructors or other routines
5438 /// that keep their arguments in this structure)
5440 public static void EmitArguments (EmitContext ec, MethodBase mb, ArrayList arguments)
5444 pd = GetParameterData (mb);
5449 // If we are calling a params method with no arguments, special case it
5451 if (arguments == null){
5452 if (pd != null && pd.Count > 0 &&
5453 pd.ParameterModifier (0) == Parameter.Modifier.PARAMS){
5454 ILGenerator ig = ec.ig;
5456 IntConstant.EmitInt (ig, 0);
5457 ig.Emit (OpCodes.Newarr, TypeManager.GetElementType (pd.ParameterType (0)));
5463 int top = arguments.Count;
5465 for (int i = 0; i < top; i++){
5466 Argument a = (Argument) arguments [i];
5469 if (pd.ParameterModifier (i) == Parameter.Modifier.PARAMS){
5471 // Special case if we are passing the same data as the
5472 // params argument, do not put it in an array.
5474 if (pd.ParameterType (i) == a.Type)
5477 EmitParams (ec, i, arguments);
5485 if (pd != null && pd.Count > top &&
5486 pd.ParameterModifier (top) == Parameter.Modifier.PARAMS){
5487 ILGenerator ig = ec.ig;
5489 IntConstant.EmitInt (ig, 0);
5490 ig.Emit (OpCodes.Newarr, TypeManager.GetElementType (pd.ParameterType (top)));
5495 /// This checks the ConditionalAttribute on the method
5497 static bool IsMethodExcluded (MethodBase method, EmitContext ec)
5499 if (method.IsConstructor)
5502 IMethodData md = TypeManager.GetMethod (method);
5504 return md.IsExcluded (ec);
5506 // For some methods (generated by delegate class) GetMethod returns null
5507 // because they are not included in builder_to_method table
5508 if (method.DeclaringType is TypeBuilder)
5511 return AttributeTester.IsConditionalMethodExcluded (method);
5515 /// is_base tells whether we want to force the use of the `call'
5516 /// opcode instead of using callvirt. Call is required to call
5517 /// a specific method, while callvirt will always use the most
5518 /// recent method in the vtable.
5520 /// is_static tells whether this is an invocation on a static method
5522 /// instance_expr is an expression that represents the instance
5523 /// it must be non-null if is_static is false.
5525 /// method is the method to invoke.
5527 /// Arguments is the list of arguments to pass to the method or constructor.
5529 public static void EmitCall (EmitContext ec, bool is_base,
5530 bool is_static, Expression instance_expr,
5531 MethodBase method, ArrayList Arguments, Location loc)
5533 ILGenerator ig = ec.ig;
5534 bool struct_call = false;
5535 bool this_call = false;
5537 Type decl_type = method.DeclaringType;
5539 if (!RootContext.StdLib) {
5540 // Replace any calls to the system's System.Array type with calls to
5541 // the newly created one.
5542 if (method == TypeManager.system_int_array_get_length)
5543 method = TypeManager.int_array_get_length;
5544 else if (method == TypeManager.system_int_array_get_rank)
5545 method = TypeManager.int_array_get_rank;
5546 else if (method == TypeManager.system_object_array_clone)
5547 method = TypeManager.object_array_clone;
5548 else if (method == TypeManager.system_int_array_get_length_int)
5549 method = TypeManager.int_array_get_length_int;
5550 else if (method == TypeManager.system_int_array_get_lower_bound_int)
5551 method = TypeManager.int_array_get_lower_bound_int;
5552 else if (method == TypeManager.system_int_array_get_upper_bound_int)
5553 method = TypeManager.int_array_get_upper_bound_int;
5554 else if (method == TypeManager.system_void_array_copyto_array_int)
5555 method = TypeManager.void_array_copyto_array_int;
5559 // This checks ObsoleteAttribute on the method and on the declaring type
5561 ObsoleteAttribute oa = AttributeTester.GetMethodObsoleteAttribute (method);
5563 AttributeTester.Report_ObsoleteMessage (oa, TypeManager.CSharpSignature (method), loc);
5565 oa = AttributeTester.GetObsoleteAttribute (method.DeclaringType);
5567 AttributeTester.Report_ObsoleteMessage (oa, method.DeclaringType.FullName, loc);
5571 oa = AttributeTester.GetObsoleteAttribute (method.DeclaringType);
5573 AttributeTester.Report_ObsoleteMessage (oa, method.DeclaringType.FullName, loc);
5576 if (IsMethodExcluded (method, ec))
5580 if (TypeManager.IsValueType (decl_type))
5583 // If this is ourselves, push "this"
5585 if (instance_expr == null){
5587 ig.Emit (OpCodes.Ldarg_0);
5589 Type itype = instance_expr.Type;
5592 // Push the instance expression
5594 if (TypeManager.IsValueType (itype)){
5596 // Special case: calls to a function declared in a
5597 // reference-type with a value-type argument need
5598 // to have their value boxed.
5599 if (decl_type.IsValueType || itype.IsGenericParameter){
5601 // If the expression implements IMemoryLocation, then
5602 // we can optimize and use AddressOf on the
5605 // If not we have to use some temporary storage for
5607 if (instance_expr is IMemoryLocation){
5608 ((IMemoryLocation)instance_expr).
5609 AddressOf (ec, AddressOp.LoadStore);
5612 instance_expr.Emit (ec);
5613 LocalBuilder temp = ig.DeclareLocal (itype);
5614 ig.Emit (OpCodes.Stloc, temp);
5615 ig.Emit (OpCodes.Ldloca, temp);
5617 if (itype.IsGenericParameter)
5618 ig.Emit (OpCodes.Constrained, itype);
5622 instance_expr.Emit (ec);
5623 ig.Emit (OpCodes.Box, itype);
5626 instance_expr.Emit (ec);
5630 EmitArguments (ec, method, Arguments);
5634 // and DoFoo is not virtual, you can omit the callvirt,
5635 // because you don't need the null checking behavior.
5637 if (is_static || struct_call || is_base || (this_call && !method.IsVirtual)){
5638 if (method is MethodInfo) {
5639 ig.Emit (OpCodes.Call, (MethodInfo) method);
5641 ig.Emit (OpCodes.Call, (ConstructorInfo) method);
5643 if (method is MethodInfo)
5644 ig.Emit (OpCodes.Callvirt, (MethodInfo) method);
5646 ig.Emit (OpCodes.Callvirt, (ConstructorInfo) method);
5650 public override void Emit (EmitContext ec)
5652 MethodGroupExpr mg = (MethodGroupExpr) this.expr;
5654 EmitCall (ec, is_base, method.IsStatic, mg.InstanceExpression, method, Arguments, loc);
5657 public override void EmitStatement (EmitContext ec)
5662 // Pop the return value if there is one
5664 if (method is MethodInfo){
5665 Type ret = ((MethodInfo)method).ReturnType;
5666 if (TypeManager.TypeToCoreType (ret) != TypeManager.void_type)
5667 ec.ig.Emit (OpCodes.Pop);
5672 public class InvocationOrCast : ExpressionStatement
5675 Expression argument;
5677 public InvocationOrCast (Expression expr, Expression argument, Location loc)
5680 this.argument = argument;
5684 public override Expression DoResolve (EmitContext ec)
5687 // First try to resolve it as a cast.
5689 type = ec.DeclSpace.ResolveType (expr, true, loc);
5691 Cast cast = new Cast (new TypeExpression (type, loc), argument, loc);
5692 return cast.Resolve (ec);
5696 // This can either be a type or a delegate invocation.
5697 // Let's just resolve it and see what we'll get.
5699 expr = expr.Resolve (ec, ResolveFlags.Type | ResolveFlags.VariableOrValue);
5704 // Ok, so it's a Cast.
5706 if (expr.eclass == ExprClass.Type) {
5707 Cast cast = new Cast (new TypeExpression (expr.Type, loc), argument, loc);
5708 return cast.Resolve (ec);
5712 // It's a delegate invocation.
5714 if (!TypeManager.IsDelegateType (expr.Type)) {
5715 Error (149, "Method name expected");
5719 ArrayList args = new ArrayList ();
5720 args.Add (new Argument (argument, Argument.AType.Expression));
5721 DelegateInvocation invocation = new DelegateInvocation (expr, args, loc);
5722 return invocation.Resolve (ec);
5727 Error (201, "Only assignment, call, increment, decrement and new object " +
5728 "expressions can be used as a statement");
5731 public override ExpressionStatement ResolveStatement (EmitContext ec)
5734 // First try to resolve it as a cast.
5736 type = ec.DeclSpace.ResolveType (expr, true, loc);
5743 // This can either be a type or a delegate invocation.
5744 // Let's just resolve it and see what we'll get.
5746 expr = expr.Resolve (ec, ResolveFlags.Type | ResolveFlags.VariableOrValue);
5747 if ((expr == null) || (expr.eclass == ExprClass.Type)) {
5753 // It's a delegate invocation.
5755 if (!TypeManager.IsDelegateType (expr.Type)) {
5756 Error (149, "Method name expected");
5760 ArrayList args = new ArrayList ();
5761 args.Add (new Argument (argument, Argument.AType.Expression));
5762 DelegateInvocation invocation = new DelegateInvocation (expr, args, loc);
5763 return invocation.ResolveStatement (ec);
5766 public override void Emit (EmitContext ec)
5768 throw new Exception ("Cannot happen");
5771 public override void EmitStatement (EmitContext ec)
5773 throw new Exception ("Cannot happen");
5778 // This class is used to "disable" the code generation for the
5779 // temporary variable when initializing value types.
5781 class EmptyAddressOf : EmptyExpression, IMemoryLocation {
5782 public void AddressOf (EmitContext ec, AddressOp Mode)
5789 /// Implements the new expression
5791 public class New : ExpressionStatement, IMemoryLocation {
5792 public readonly ArrayList Arguments;
5795 // During bootstrap, it contains the RequestedType,
5796 // but if `type' is not null, it *might* contain a NewDelegate
5797 // (because of field multi-initialization)
5799 public Expression RequestedType;
5801 MethodBase method = null;
5804 // If set, the new expression is for a value_target, and
5805 // we will not leave anything on the stack.
5807 Expression value_target;
5808 bool value_target_set = false;
5809 bool is_type_parameter = false;
5811 public New (Expression requested_type, ArrayList arguments, Location l)
5813 RequestedType = requested_type;
5814 Arguments = arguments;
5818 public bool SetValueTypeVariable (Expression value)
5820 value_target = value;
5821 value_target_set = true;
5822 if (!(value_target is IMemoryLocation)){
5823 Error_UnexpectedKind ("variable");
5830 // This function is used to disable the following code sequence for
5831 // value type initialization:
5833 // AddressOf (temporary)
5837 // Instead the provide will have provided us with the address on the
5838 // stack to store the results.
5840 static Expression MyEmptyExpression;
5842 public void DisableTemporaryValueType ()
5844 if (MyEmptyExpression == null)
5845 MyEmptyExpression = new EmptyAddressOf ();
5848 // To enable this, look into:
5849 // test-34 and test-89 and self bootstrapping.
5851 // For instance, we can avoid a copy by using `newobj'
5852 // instead of Call + Push-temp on value types.
5853 // value_target = MyEmptyExpression;
5856 public override Expression DoResolve (EmitContext ec)
5859 // The New DoResolve might be called twice when initializing field
5860 // expressions (see EmitFieldInitializers, the call to
5861 // GetInitializerExpression will perform a resolve on the expression,
5862 // and later the assign will trigger another resolution
5864 // This leads to bugs (#37014)
5867 if (RequestedType is NewDelegate)
5868 return RequestedType;
5872 type = ec.DeclSpace.ResolveType (RequestedType, false, loc);
5877 CheckObsoleteAttribute (type);
5879 bool IsDelegate = TypeManager.IsDelegateType (type);
5882 RequestedType = (new NewDelegate (type, Arguments, loc)).Resolve (ec);
5883 if (RequestedType != null)
5884 if (!(RequestedType is NewDelegate))
5885 throw new Exception ("NewDelegate.Resolve returned a non NewDelegate: " + RequestedType.GetType ());
5886 return RequestedType;
5889 if (type.IsGenericParameter) {
5890 if (!TypeManager.HasConstructorConstraint (type)) {
5891 Error (304, String.Format (
5892 "Cannot create an instance of the " +
5893 "variable type '{0}' because it " +
5894 "doesn't have the new() constraint",
5899 if ((Arguments != null) && (Arguments.Count != 0)) {
5900 Error (417, String.Format (
5901 "`{0}': cannot provide arguments " +
5902 "when creating an instance of a " +
5903 "variable type.", type));
5907 is_type_parameter = true;
5908 eclass = ExprClass.Value;
5910 } else if (type.IsInterface || type.IsAbstract){
5911 Error (144, "It is not possible to create instances of interfaces or abstract classes");
5915 bool is_struct = type.IsValueType;
5916 eclass = ExprClass.Value;
5919 // SRE returns a match for .ctor () on structs (the object constructor),
5920 // so we have to manually ignore it.
5922 if (is_struct && Arguments == null)
5926 ml = MemberLookupFinal (ec, type, type, ".ctor",
5927 // For member-lookup, treat 'new Foo (bar)' as call to 'foo.ctor (bar)', where 'foo' is of type 'Foo'.
5928 MemberTypes.Constructor,
5929 AllBindingFlags | BindingFlags.DeclaredOnly, loc);
5934 if (! (ml is MethodGroupExpr)){
5936 ml.Error_UnexpectedKind ("method group");
5942 if (Arguments != null){
5943 foreach (Argument a in Arguments){
5944 if (!a.Resolve (ec, loc))
5949 method = Invocation.OverloadResolve (
5950 ec, (MethodGroupExpr) ml, Arguments, false, loc);
5954 if (method == null) {
5955 if (!is_struct || Arguments.Count > 0) {
5956 Error (1501, String.Format (
5957 "New invocation: Can not find a constructor in `{0}' for this argument list",
5958 TypeManager.CSharpName (type)));
5966 bool DoEmitTypeParameter (EmitContext ec)
5968 ILGenerator ig = ec.ig;
5970 ig.Emit (OpCodes.Ldtoken, type);
5971 ig.Emit (OpCodes.Call, TypeManager.system_type_get_type_from_handle);
5972 ig.Emit (OpCodes.Call, TypeManager.activator_create_instance);
5973 ig.Emit (OpCodes.Unbox_Any, type);
5979 // This DoEmit can be invoked in two contexts:
5980 // * As a mechanism that will leave a value on the stack (new object)
5981 // * As one that wont (init struct)
5983 // You can control whether a value is required on the stack by passing
5984 // need_value_on_stack. The code *might* leave a value on the stack
5985 // so it must be popped manually
5987 // If we are dealing with a ValueType, we have a few
5988 // situations to deal with:
5990 // * The target is a ValueType, and we have been provided
5991 // the instance (this is easy, we are being assigned).
5993 // * The target of New is being passed as an argument,
5994 // to a boxing operation or a function that takes a
5997 // In this case, we need to create a temporary variable
5998 // that is the argument of New.
6000 // Returns whether a value is left on the stack
6002 bool DoEmit (EmitContext ec, bool need_value_on_stack)
6004 bool is_value_type = type.IsValueType;
6005 ILGenerator ig = ec.ig;
6010 // Allow DoEmit() to be called multiple times.
6011 // We need to create a new LocalTemporary each time since
6012 // you can't share LocalBuilders among ILGeneators.
6013 if (!value_target_set)
6014 value_target = new LocalTemporary (ec, type);
6016 ml = (IMemoryLocation) value_target;
6017 ml.AddressOf (ec, AddressOp.Store);
6021 Invocation.EmitArguments (ec, method, Arguments);
6025 ig.Emit (OpCodes.Initobj, type);
6027 ig.Emit (OpCodes.Call, (ConstructorInfo) method);
6028 if (need_value_on_stack){
6029 value_target.Emit (ec);
6034 ig.Emit (OpCodes.Newobj, (ConstructorInfo) method);
6039 public override void Emit (EmitContext ec)
6041 if (is_type_parameter)
6042 DoEmitTypeParameter (ec);
6047 public override void EmitStatement (EmitContext ec)
6049 if (is_type_parameter)
6050 throw new InvalidOperationException ();
6052 if (DoEmit (ec, false))
6053 ec.ig.Emit (OpCodes.Pop);
6056 public void AddressOf (EmitContext ec, AddressOp Mode)
6058 if (is_type_parameter)
6059 throw new InvalidOperationException ();
6061 if (!type.IsValueType){
6063 // We throw an exception. So far, I believe we only need to support
6065 // foreach (int j in new StructType ())
6068 throw new Exception ("AddressOf should not be used for classes");
6071 if (!value_target_set)
6072 value_target = new LocalTemporary (ec, type);
6074 IMemoryLocation ml = (IMemoryLocation) value_target;
6075 ml.AddressOf (ec, AddressOp.Store);
6077 Invocation.EmitArguments (ec, method, Arguments);
6080 ec.ig.Emit (OpCodes.Initobj, type);
6082 ec.ig.Emit (OpCodes.Call, (ConstructorInfo) method);
6084 ((IMemoryLocation) value_target).AddressOf (ec, Mode);
6089 /// 14.5.10.2: Represents an array creation expression.
6093 /// There are two possible scenarios here: one is an array creation
6094 /// expression that specifies the dimensions and optionally the
6095 /// initialization data and the other which does not need dimensions
6096 /// specified but where initialization data is mandatory.
6098 public class ArrayCreation : Expression {
6099 Expression requested_base_type;
6100 ArrayList initializers;
6103 // The list of Argument types.
6104 // This is used to construct the `newarray' or constructor signature
6106 ArrayList arguments;
6109 // Method used to create the array object.
6111 MethodBase new_method = null;
6113 Type array_element_type;
6114 Type underlying_type;
6115 bool is_one_dimensional = false;
6116 bool is_builtin_type = false;
6117 bool expect_initializers = false;
6118 int num_arguments = 0;
6122 ArrayList array_data;
6127 // The number of array initializers that we can handle
6128 // via the InitializeArray method - through EmitStaticInitializers
6130 int num_automatic_initializers;
6132 const int max_automatic_initializers = 6;
6134 public ArrayCreation (Expression requested_base_type, ArrayList exprs, string rank, ArrayList initializers, Location l)
6136 this.requested_base_type = requested_base_type;
6137 this.initializers = initializers;
6141 arguments = new ArrayList ();
6143 foreach (Expression e in exprs) {
6144 arguments.Add (new Argument (e, Argument.AType.Expression));
6149 public ArrayCreation (Expression requested_base_type, string rank, ArrayList initializers, Location l)
6151 this.requested_base_type = requested_base_type;
6152 this.initializers = initializers;
6156 //this.rank = rank.Substring (0, rank.LastIndexOf ('['));
6158 //string tmp = rank.Substring (rank.LastIndexOf ('['));
6160 //dimensions = tmp.Length - 1;
6161 expect_initializers = true;
6164 public Expression FormArrayType (Expression base_type, int idx_count, string rank)
6166 StringBuilder sb = new StringBuilder (rank);
6169 for (int i = 1; i < idx_count; i++)
6174 return new ComposedCast (base_type, sb.ToString (), loc);
6177 void Error_IncorrectArrayInitializer ()
6179 Error (178, "Incorrectly structured array initializer");
6182 public bool CheckIndices (EmitContext ec, ArrayList probe, int idx, bool specified_dims)
6184 if (specified_dims) {
6185 Argument a = (Argument) arguments [idx];
6187 if (!a.Resolve (ec, loc))
6190 if (!(a.Expr is Constant)) {
6191 Error (150, "A constant value is expected");
6195 int value = (int) ((Constant) a.Expr).GetValue ();
6197 if (value != probe.Count) {
6198 Error_IncorrectArrayInitializer ();
6202 bounds [idx] = value;
6205 int child_bounds = -1;
6206 foreach (object o in probe) {
6207 if (o is ArrayList) {
6208 int current_bounds = ((ArrayList) o).Count;
6210 if (child_bounds == -1)
6211 child_bounds = current_bounds;
6213 else if (child_bounds != current_bounds){
6214 Error_IncorrectArrayInitializer ();
6217 if (specified_dims && (idx + 1 >= arguments.Count)){
6218 Error (623, "Array initializers can only be used in a variable or field initializer, try using the new expression");
6222 bool ret = CheckIndices (ec, (ArrayList) o, idx + 1, specified_dims);
6226 if (child_bounds != -1){
6227 Error_IncorrectArrayInitializer ();
6231 Expression tmp = (Expression) o;
6232 tmp = tmp.Resolve (ec);
6236 // Console.WriteLine ("I got: " + tmp);
6237 // Handle initialization from vars, fields etc.
6239 Expression conv = Convert.ImplicitConversionRequired (
6240 ec, tmp, underlying_type, loc);
6245 if (conv is StringConstant || conv is DecimalConstant || conv is NullCast) {
6246 // These are subclasses of Constant that can appear as elements of an
6247 // array that cannot be statically initialized (with num_automatic_initializers
6248 // > max_automatic_initializers), so num_automatic_initializers should be left as zero.
6249 array_data.Add (conv);
6250 } else if (conv is Constant) {
6251 // These are the types of Constant that can appear in arrays that can be
6252 // statically allocated.
6253 array_data.Add (conv);
6254 num_automatic_initializers++;
6256 array_data.Add (conv);
6263 public void UpdateIndices (EmitContext ec)
6266 for (ArrayList probe = initializers; probe != null;) {
6267 if (probe.Count > 0 && probe [0] is ArrayList) {
6268 Expression e = new IntConstant (probe.Count);
6269 arguments.Add (new Argument (e, Argument.AType.Expression));
6271 bounds [i++] = probe.Count;
6273 probe = (ArrayList) probe [0];
6276 Expression e = new IntConstant (probe.Count);
6277 arguments.Add (new Argument (e, Argument.AType.Expression));
6279 bounds [i++] = probe.Count;
6286 public bool ValidateInitializers (EmitContext ec, Type array_type)
6288 if (initializers == null) {
6289 if (expect_initializers)
6295 if (underlying_type == null)
6299 // We use this to store all the date values in the order in which we
6300 // will need to store them in the byte blob later
6302 array_data = new ArrayList ();
6303 bounds = new Hashtable ();
6307 if (arguments != null) {
6308 ret = CheckIndices (ec, initializers, 0, true);
6311 arguments = new ArrayList ();
6313 ret = CheckIndices (ec, initializers, 0, false);
6320 if (arguments.Count != dimensions) {
6321 Error_IncorrectArrayInitializer ();
6329 void Error_NegativeArrayIndex ()
6331 Error (284, "Can not create array with a negative size");
6335 // Converts `source' to an int, uint, long or ulong.
6337 Expression ExpressionToArrayArgument (EmitContext ec, Expression source)
6341 bool old_checked = ec.CheckState;
6342 ec.CheckState = true;
6344 target = Convert.ImplicitConversion (ec, source, TypeManager.int32_type, loc);
6345 if (target == null){
6346 target = Convert.ImplicitConversion (ec, source, TypeManager.uint32_type, loc);
6347 if (target == null){
6348 target = Convert.ImplicitConversion (ec, source, TypeManager.int64_type, loc);
6349 if (target == null){
6350 target = Convert.ImplicitConversion (ec, source, TypeManager.uint64_type, loc);
6352 Convert.Error_CannotImplicitConversion (loc, source.Type, TypeManager.int32_type);
6356 ec.CheckState = old_checked;
6359 // Only positive constants are allowed at compile time
6361 if (target is Constant){
6362 if (target is IntConstant){
6363 if (((IntConstant) target).Value < 0){
6364 Error_NegativeArrayIndex ();
6369 if (target is LongConstant){
6370 if (((LongConstant) target).Value < 0){
6371 Error_NegativeArrayIndex ();
6382 // Creates the type of the array
6384 bool LookupType (EmitContext ec)
6386 StringBuilder array_qualifier = new StringBuilder (rank);
6389 // `In the first form allocates an array instace of the type that results
6390 // from deleting each of the individual expression from the expression list'
6392 if (num_arguments > 0) {
6393 array_qualifier.Append ("[");
6394 for (int i = num_arguments-1; i > 0; i--)
6395 array_qualifier.Append (",");
6396 array_qualifier.Append ("]");
6402 Expression array_type_expr;
6403 array_type_expr = new ComposedCast (requested_base_type, array_qualifier.ToString (), loc);
6404 type = ec.DeclSpace.ResolveType (array_type_expr, false, loc);
6409 underlying_type = type;
6410 if (underlying_type.IsArray)
6411 underlying_type = TypeManager.GetElementType (underlying_type);
6412 dimensions = type.GetArrayRank ();
6417 public override Expression DoResolve (EmitContext ec)
6421 if (!LookupType (ec))
6425 // First step is to validate the initializers and fill
6426 // in any missing bits
6428 if (!ValidateInitializers (ec, type))
6431 if (arguments == null)
6434 arg_count = arguments.Count;
6435 foreach (Argument a in arguments){
6436 if (!a.Resolve (ec, loc))
6439 Expression real_arg = ExpressionToArrayArgument (ec, a.Expr, loc);
6440 if (real_arg == null)
6447 array_element_type = TypeManager.GetElementType (type);
6449 if (arg_count == 1) {
6450 is_one_dimensional = true;
6451 eclass = ExprClass.Value;
6455 is_builtin_type = TypeManager.IsBuiltinType (type);
6457 if (is_builtin_type) {
6460 ml = MemberLookup (ec, type, ".ctor", MemberTypes.Constructor,
6461 AllBindingFlags, loc);
6463 if (!(ml is MethodGroupExpr)) {
6464 ml.Error_UnexpectedKind ("method group");
6469 Error (-6, "New invocation: Can not find a constructor for " +
6470 "this argument list");
6474 new_method = Invocation.OverloadResolve (
6475 ec, (MethodGroupExpr) ml, arguments, false, loc);
6477 if (new_method == null) {
6478 Error (-6, "New invocation: Can not find a constructor for " +
6479 "this argument list");
6483 eclass = ExprClass.Value;
6486 ModuleBuilder mb = CodeGen.Module.Builder;
6487 ArrayList args = new ArrayList ();
6489 if (arguments != null) {
6490 for (int i = 0; i < arg_count; i++)
6491 args.Add (TypeManager.int32_type);
6494 Type [] arg_types = null;
6497 arg_types = new Type [args.Count];
6499 args.CopyTo (arg_types, 0);
6501 new_method = mb.GetArrayMethod (type, ".ctor", CallingConventions.HasThis, null,
6504 if (new_method == null) {
6505 Error (-6, "New invocation: Can not find a constructor for " +
6506 "this argument list");
6510 eclass = ExprClass.Value;
6515 public static byte [] MakeByteBlob (ArrayList array_data, Type underlying_type, Location loc)
6520 int count = array_data.Count;
6522 if (underlying_type.IsEnum)
6523 underlying_type = TypeManager.EnumToUnderlying (underlying_type);
6525 factor = GetTypeSize (underlying_type);
6527 throw new Exception ("unrecognized type in MakeByteBlob: " + underlying_type);
6529 data = new byte [(count * factor + 4) & ~3];
6532 for (int i = 0; i < count; ++i) {
6533 object v = array_data [i];
6535 if (v is EnumConstant)
6536 v = ((EnumConstant) v).Child;
6538 if (v is Constant && !(v is StringConstant))
6539 v = ((Constant) v).GetValue ();
6545 if (underlying_type == TypeManager.int64_type){
6546 if (!(v is Expression)){
6547 long val = (long) v;
6549 for (int j = 0; j < factor; ++j) {
6550 data [idx + j] = (byte) (val & 0xFF);
6554 } else if (underlying_type == TypeManager.uint64_type){
6555 if (!(v is Expression)){
6556 ulong val = (ulong) v;
6558 for (int j = 0; j < factor; ++j) {
6559 data [idx + j] = (byte) (val & 0xFF);
6563 } else if (underlying_type == TypeManager.float_type) {
6564 if (!(v is Expression)){
6565 element = BitConverter.GetBytes ((float) v);
6567 for (int j = 0; j < factor; ++j)
6568 data [idx + j] = element [j];
6570 } else if (underlying_type == TypeManager.double_type) {
6571 if (!(v is Expression)){
6572 element = BitConverter.GetBytes ((double) v);
6574 for (int j = 0; j < factor; ++j)
6575 data [idx + j] = element [j];
6577 } else if (underlying_type == TypeManager.char_type){
6578 if (!(v is Expression)){
6579 int val = (int) ((char) v);
6581 data [idx] = (byte) (val & 0xff);
6582 data [idx+1] = (byte) (val >> 8);
6584 } else if (underlying_type == TypeManager.short_type){
6585 if (!(v is Expression)){
6586 int val = (int) ((short) v);
6588 data [idx] = (byte) (val & 0xff);
6589 data [idx+1] = (byte) (val >> 8);
6591 } else if (underlying_type == TypeManager.ushort_type){
6592 if (!(v is Expression)){
6593 int val = (int) ((ushort) v);
6595 data [idx] = (byte) (val & 0xff);
6596 data [idx+1] = (byte) (val >> 8);
6598 } else if (underlying_type == TypeManager.int32_type) {
6599 if (!(v is Expression)){
6602 data [idx] = (byte) (val & 0xff);
6603 data [idx+1] = (byte) ((val >> 8) & 0xff);
6604 data [idx+2] = (byte) ((val >> 16) & 0xff);
6605 data [idx+3] = (byte) (val >> 24);
6607 } else if (underlying_type == TypeManager.uint32_type) {
6608 if (!(v is Expression)){
6609 uint val = (uint) v;
6611 data [idx] = (byte) (val & 0xff);
6612 data [idx+1] = (byte) ((val >> 8) & 0xff);
6613 data [idx+2] = (byte) ((val >> 16) & 0xff);
6614 data [idx+3] = (byte) (val >> 24);
6616 } else if (underlying_type == TypeManager.sbyte_type) {
6617 if (!(v is Expression)){
6618 sbyte val = (sbyte) v;
6619 data [idx] = (byte) val;
6621 } else if (underlying_type == TypeManager.byte_type) {
6622 if (!(v is Expression)){
6623 byte val = (byte) v;
6624 data [idx] = (byte) val;
6626 } else if (underlying_type == TypeManager.bool_type) {
6627 if (!(v is Expression)){
6628 bool val = (bool) v;
6629 data [idx] = (byte) (val ? 1 : 0);
6631 } else if (underlying_type == TypeManager.decimal_type){
6632 if (!(v is Expression)){
6633 int [] bits = Decimal.GetBits ((decimal) v);
6636 // FIXME: For some reason, this doesn't work on the MS runtime.
6637 int [] nbits = new int [4];
6638 nbits [0] = bits [3];
6639 nbits [1] = bits [2];
6640 nbits [2] = bits [0];
6641 nbits [3] = bits [1];
6643 for (int j = 0; j < 4; j++){
6644 data [p++] = (byte) (nbits [j] & 0xff);
6645 data [p++] = (byte) ((nbits [j] >> 8) & 0xff);
6646 data [p++] = (byte) ((nbits [j] >> 16) & 0xff);
6647 data [p++] = (byte) (nbits [j] >> 24);
6651 throw new Exception ("Unrecognized type in MakeByteBlob: " + underlying_type);
6660 // Emits the initializers for the array
6662 void EmitStaticInitializers (EmitContext ec)
6665 // First, the static data
6668 ILGenerator ig = ec.ig;
6670 byte [] data = MakeByteBlob (array_data, underlying_type, loc);
6672 fb = RootContext.MakeStaticData (data);
6674 ig.Emit (OpCodes.Dup);
6675 ig.Emit (OpCodes.Ldtoken, fb);
6676 ig.Emit (OpCodes.Call,
6677 TypeManager.void_initializearray_array_fieldhandle);
6681 // Emits pieces of the array that can not be computed at compile
6682 // time (variables and string locations).
6684 // This always expect the top value on the stack to be the array
6686 void EmitDynamicInitializers (EmitContext ec)
6688 ILGenerator ig = ec.ig;
6689 int dims = bounds.Count;
6690 int [] current_pos = new int [dims];
6691 int top = array_data.Count;
6693 MethodInfo set = null;
6697 ModuleBuilder mb = null;
6698 mb = CodeGen.Module.Builder;
6699 args = new Type [dims + 1];
6702 for (j = 0; j < dims; j++)
6703 args [j] = TypeManager.int32_type;
6705 args [j] = array_element_type;
6707 set = mb.GetArrayMethod (
6709 CallingConventions.HasThis | CallingConventions.Standard,
6710 TypeManager.void_type, args);
6713 for (int i = 0; i < top; i++){
6715 Expression e = null;
6717 if (array_data [i] is Expression)
6718 e = (Expression) array_data [i];
6722 // Basically we do this for string literals and
6723 // other non-literal expressions
6725 if (e is EnumConstant){
6726 e = ((EnumConstant) e).Child;
6729 if (e is StringConstant || e is DecimalConstant || !(e is Constant) ||
6730 num_automatic_initializers <= max_automatic_initializers) {
6731 Type etype = e.Type;
6733 ig.Emit (OpCodes.Dup);
6735 for (int idx = 0; idx < dims; idx++)
6736 IntConstant.EmitInt (ig, current_pos [idx]);
6739 // If we are dealing with a struct, get the
6740 // address of it, so we can store it.
6743 etype.IsSubclassOf (TypeManager.value_type) &&
6744 (!TypeManager.IsBuiltinOrEnum (etype) ||
6745 etype == TypeManager.decimal_type)) {
6750 // Let new know that we are providing
6751 // the address where to store the results
6753 n.DisableTemporaryValueType ();
6756 ig.Emit (OpCodes.Ldelema, etype);
6762 ArrayAccess.EmitStoreOpcode (ig, array_element_type);
6764 ig.Emit (OpCodes.Call, set);
6772 for (int j = dims - 1; j >= 0; j--){
6774 if (current_pos [j] < (int) bounds [j])
6776 current_pos [j] = 0;
6781 void EmitArrayArguments (EmitContext ec)
6783 ILGenerator ig = ec.ig;
6785 foreach (Argument a in arguments) {
6786 Type atype = a.Type;
6789 if (atype == TypeManager.uint64_type)
6790 ig.Emit (OpCodes.Conv_Ovf_U4);
6791 else if (atype == TypeManager.int64_type)
6792 ig.Emit (OpCodes.Conv_Ovf_I4);
6796 public override void Emit (EmitContext ec)
6798 ILGenerator ig = ec.ig;
6800 EmitArrayArguments (ec);
6801 if (is_one_dimensional)
6802 ig.Emit (OpCodes.Newarr, array_element_type);
6804 if (is_builtin_type)
6805 ig.Emit (OpCodes.Newobj, (ConstructorInfo) new_method);
6807 ig.Emit (OpCodes.Newobj, (MethodInfo) new_method);
6810 if (initializers != null){
6812 // FIXME: Set this variable correctly.
6814 bool dynamic_initializers = true;
6816 // This will never be true for array types that cannot be statically
6817 // initialized. num_automatic_initializers will always be zero. See
6819 if (num_automatic_initializers > max_automatic_initializers)
6820 EmitStaticInitializers (ec);
6822 if (dynamic_initializers)
6823 EmitDynamicInitializers (ec);
6827 public object EncodeAsAttribute ()
6829 if (!is_one_dimensional){
6830 Report.Error (-211, Location, "attribute can not encode multi-dimensional arrays");
6834 if (array_data == null){
6835 Report.Error (-212, Location, "array should be initialized when passing it to an attribute");
6839 object [] ret = new object [array_data.Count];
6841 foreach (Expression e in array_data){
6844 if (e is NullLiteral)
6847 if (!Attribute.GetAttributeArgumentExpression (e, Location, out v))
6855 public Expression TurnIntoConstant ()
6858 // Should use something like the above attribute thing.
6859 // It should return a subclass of Constant that just returns
6860 // the computed value of the array
6862 throw new Exception ("Does not support yet Turning array into a Constant");
6867 /// Represents the `this' construct
6869 public class This : Expression, IAssignMethod, IMemoryLocation, IVariable {
6872 VariableInfo variable_info;
6874 public This (Block block, Location loc)
6880 public This (Location loc)
6885 public VariableInfo VariableInfo {
6886 get { return variable_info; }
6889 public bool VerifyFixed (bool is_expression)
6891 if ((variable_info == null) || (variable_info.LocalInfo == null))
6894 return variable_info.LocalInfo.IsFixed;
6897 public bool ResolveBase (EmitContext ec)
6899 eclass = ExprClass.Variable;
6901 if (ec.TypeContainer.CurrentType != null)
6902 type = ec.TypeContainer.CurrentType.ResolveType (ec);
6904 type = ec.ContainerType;
6907 Error (26, "Keyword this not valid in static code");
6911 if ((block != null) && (block.ThisVariable != null))
6912 variable_info = block.ThisVariable.VariableInfo;
6917 public override Expression DoResolve (EmitContext ec)
6919 if (!ResolveBase (ec))
6922 if ((variable_info != null) && !variable_info.IsAssigned (ec)) {
6923 Error (188, "The this object cannot be used before all " +
6924 "of its fields are assigned to");
6925 variable_info.SetAssigned (ec);
6929 if (ec.IsFieldInitializer) {
6930 Error (27, "Keyword `this' can't be used outside a constructor, " +
6931 "a method or a property.");
6938 override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
6940 if (!ResolveBase (ec))
6943 if (variable_info != null)
6944 variable_info.SetAssigned (ec);
6946 if (ec.TypeContainer is Class){
6947 Error (1604, "Cannot assign to `this'");
6954 public override void Emit (EmitContext ec)
6956 ILGenerator ig = ec.ig;
6959 if (ec.TypeContainer is Struct)
6960 ig.Emit (OpCodes.Ldobj, type);
6963 public void EmitAssign (EmitContext ec, Expression source)
6965 ILGenerator ig = ec.ig;
6967 if (ec.TypeContainer is Struct){
6970 ig.Emit (OpCodes.Stobj, type);
6973 ig.Emit (OpCodes.Starg, 0);
6977 public void AddressOf (EmitContext ec, AddressOp mode)
6982 // FIGURE OUT WHY LDARG_S does not work
6984 // consider: struct X { int val; int P { set { val = value; }}}
6986 // Yes, this looks very bad. Look at `NOTAS' for
6988 // ec.ig.Emit (OpCodes.Ldarga_S, (byte) 0);
6993 // This produces the value that renders an instance, used by the iterators code
6995 public class ProxyInstance : Expression, IMemoryLocation {
6996 public override Expression DoResolve (EmitContext ec)
6998 eclass = ExprClass.Variable;
6999 type = ec.ContainerType;
7003 public override void Emit (EmitContext ec)
7005 ec.ig.Emit (OpCodes.Ldarg_0);
7009 public void AddressOf (EmitContext ec, AddressOp mode)
7011 ec.ig.Emit (OpCodes.Ldarg_0);
7016 /// Implements the typeof operator
7018 public class TypeOf : Expression {
7019 public readonly Expression QueriedType;
7020 protected Type typearg;
7022 public TypeOf (Expression queried_type, Location l)
7024 QueriedType = queried_type;
7028 public override Expression DoResolve (EmitContext ec)
7030 typearg = ec.DeclSpace.ResolveType (QueriedType, false, loc);
7032 if (typearg == null)
7035 if (typearg == TypeManager.void_type) {
7036 Error (673, "System.Void cannot be used from C# - " +
7037 "use typeof (void) to get the void type object");
7041 CheckObsoleteAttribute (typearg);
7043 type = TypeManager.type_type;
7044 eclass = ExprClass.Type;
7048 public override void Emit (EmitContext ec)
7050 ec.ig.Emit (OpCodes.Ldtoken, typearg);
7051 ec.ig.Emit (OpCodes.Call, TypeManager.system_type_get_type_from_handle);
7054 public Type TypeArg {
7055 get { return typearg; }
7060 /// Implements the `typeof (void)' operator
7062 public class TypeOfVoid : TypeOf {
7063 public TypeOfVoid (Location l) : base (null, l)
7068 public override Expression DoResolve (EmitContext ec)
7070 type = TypeManager.type_type;
7071 typearg = TypeManager.void_type;
7072 eclass = ExprClass.Type;
7078 /// Implements the sizeof expression
7080 public class SizeOf : Expression {
7081 public Expression QueriedType;
7084 public SizeOf (Expression queried_type, Location l)
7086 this.QueriedType = queried_type;
7090 public override Expression DoResolve (EmitContext ec)
7094 233, loc, "Sizeof may only be used in an unsafe context " +
7095 "(consider using System.Runtime.InteropServices.Marshal.Sizeof");
7099 QueriedType = ec.DeclSpace.ResolveTypeExpr (QueriedType, false, loc);
7100 if (QueriedType == null || QueriedType.Type == null)
7103 if (QueriedType is TypeParameterExpr){
7104 ((TypeParameterExpr)QueriedType).Error_CannotUseAsUnmanagedType (loc);
7108 type_queried = QueriedType.Type;
7109 if (type_queried == null)
7112 CheckObsoleteAttribute (type_queried);
7114 if (!TypeManager.IsUnmanagedType (type_queried)){
7115 Report.Error (208, loc, "Cannot take the size of an unmanaged type (" + TypeManager.CSharpName (type_queried) + ")");
7119 type = TypeManager.int32_type;
7120 eclass = ExprClass.Value;
7124 public override void Emit (EmitContext ec)
7126 int size = GetTypeSize (type_queried);
7129 ec.ig.Emit (OpCodes.Sizeof, type_queried);
7131 IntConstant.EmitInt (ec.ig, size);
7136 /// Implements the member access expression
7138 public class MemberAccess : Expression {
7139 public string Identifier;
7140 protected Expression expr;
7141 protected TypeArguments args;
7143 public MemberAccess (Expression expr, string id, Location l)
7150 public MemberAccess (Expression expr, string id, TypeArguments args,
7152 : this (expr, id, l)
7157 public Expression Expr {
7163 public static void error176 (Location loc, string name)
7165 Report.Error (176, loc, "Static member `" +
7166 name + "' cannot be accessed " +
7167 "with an instance reference, qualify with a " +
7168 "type name instead");
7171 static bool IdenticalNameAndTypeName (EmitContext ec, Expression left_original, Location loc)
7173 if (left_original == null)
7176 if (!(left_original is SimpleName))
7179 SimpleName sn = (SimpleName) left_original;
7181 TypeExpr t = RootContext.LookupType (ec.DeclSpace, sn.Name, true, loc);
7188 public static Expression ResolveMemberAccess (EmitContext ec, Expression member_lookup,
7189 Expression left, Location loc,
7190 Expression left_original)
7192 bool left_is_type, left_is_explicit;
7194 // If `left' is null, then we're called from SimpleNameResolve and this is
7195 // a member in the currently defining class.
7197 left_is_type = ec.IsStatic || ec.IsFieldInitializer;
7198 left_is_explicit = false;
7200 // Implicitly default to `this' unless we're static.
7201 if (!ec.IsStatic && !ec.IsFieldInitializer && !ec.InEnumContext)
7202 left = ec.GetThis (loc);
7204 left_is_type = left is TypeExpr;
7205 left_is_explicit = true;
7208 if (member_lookup is FieldExpr){
7209 FieldExpr fe = (FieldExpr) member_lookup;
7210 FieldInfo fi = fe.FieldInfo;
7211 Type decl_type = fi.DeclaringType;
7213 if (fi is FieldBuilder) {
7214 Const c = TypeManager.LookupConstant ((FieldBuilder) fi);
7218 if (!c.LookupConstantValue (out o))
7221 object real_value = ((Constant) c.Expr).GetValue ();
7223 return Constantify (real_value, fi.FieldType);
7228 Type t = fi.FieldType;
7232 if (fi is FieldBuilder)
7233 o = TypeManager.GetValue ((FieldBuilder) fi);
7235 o = fi.GetValue (fi);
7237 if (decl_type.IsSubclassOf (TypeManager.enum_type)) {
7238 if (left_is_explicit && !left_is_type &&
7239 !IdenticalNameAndTypeName (ec, left_original, loc)) {
7240 error176 (loc, fe.FieldInfo.Name);
7244 Expression enum_member = MemberLookup (
7245 ec, decl_type, "value__", MemberTypes.Field,
7246 AllBindingFlags, loc);
7248 Enum en = TypeManager.LookupEnum (decl_type);
7252 c = Constantify (o, en.UnderlyingType);
7254 c = Constantify (o, enum_member.Type);
7256 return new EnumConstant (c, decl_type);
7259 Expression exp = Constantify (o, t);
7261 if (left_is_explicit && !left_is_type) {
7262 error176 (loc, fe.FieldInfo.Name);
7269 if (fi.FieldType.IsPointer && !ec.InUnsafe){
7275 if (member_lookup is EventExpr) {
7276 EventExpr ee = (EventExpr) member_lookup;
7279 // If the event is local to this class, we transform ourselves into
7283 if (ee.EventInfo.DeclaringType == ec.ContainerType ||
7284 TypeManager.IsNestedChildOf(ec.ContainerType, ee.EventInfo.DeclaringType)) {
7285 MemberInfo mi = GetFieldFromEvent (ee);
7289 // If this happens, then we have an event with its own
7290 // accessors and private field etc so there's no need
7291 // to transform ourselves.
7293 ee.InstanceExpression = left;
7297 Expression ml = ExprClassFromMemberInfo (ec, mi, loc);
7300 Report.Error (-200, loc, "Internal error!!");
7304 if (!left_is_explicit)
7307 ee.InstanceExpression = left;
7309 return ResolveMemberAccess (ec, ml, left, loc, left_original);
7313 if (member_lookup is IMemberExpr) {
7314 IMemberExpr me = (IMemberExpr) member_lookup;
7315 MethodGroupExpr mg = me as MethodGroupExpr;
7318 if ((mg != null) && left_is_explicit && left.Type.IsInterface)
7319 mg.IsExplicitImpl = left_is_explicit;
7322 if ((ec.IsFieldInitializer || ec.IsStatic) &&
7323 IdenticalNameAndTypeName (ec, left_original, loc))
7324 return member_lookup;
7326 SimpleName.Error_ObjectRefRequired (ec, loc, me.Name);
7331 if (!me.IsInstance){
7332 if (IdenticalNameAndTypeName (ec, left_original, loc))
7333 return member_lookup;
7335 if (left_is_explicit) {
7336 error176 (loc, me.Name);
7342 // Since we can not check for instance objects in SimpleName,
7343 // becaue of the rule that allows types and variables to share
7344 // the name (as long as they can be de-ambiguated later, see
7345 // IdenticalNameAndTypeName), we have to check whether left
7346 // is an instance variable in a static context
7348 // However, if the left-hand value is explicitly given, then
7349 // it is already our instance expression, so we aren't in
7353 if (ec.IsStatic && !left_is_explicit && left is IMemberExpr){
7354 IMemberExpr mexp = (IMemberExpr) left;
7356 if (!mexp.IsStatic){
7357 SimpleName.Error_ObjectRefRequired (ec, loc, mexp.Name);
7362 if ((mg != null) && IdenticalNameAndTypeName (ec, left_original, loc))
7363 mg.IdenticalTypeName = true;
7365 me.InstanceExpression = left;
7368 return member_lookup;
7371 Console.WriteLine ("Left is: " + left);
7372 Report.Error (-100, loc, "Support for [" + member_lookup + "] is not present yet");
7373 Environment.Exit (1);
7377 public virtual Expression DoResolve (EmitContext ec, Expression right_side,
7381 throw new Exception ();
7384 // Resolve the expression with flow analysis turned off, we'll do the definite
7385 // assignment checks later. This is because we don't know yet what the expression
7386 // will resolve to - it may resolve to a FieldExpr and in this case we must do the
7387 // definite assignment check on the actual field and not on the whole struct.
7390 Expression original = expr;
7391 expr = expr.Resolve (ec, flags | ResolveFlags.DisableFlowAnalysis);
7395 if (expr is SimpleName){
7396 SimpleName child_expr = (SimpleName) expr;
7398 Expression new_expr = new SimpleName (child_expr.Name, Identifier, loc);
7400 return new_expr.Resolve (ec, flags);
7404 // TODO: I mailed Ravi about this, and apparently we can get rid
7405 // of this and put it in the right place.
7407 // Handle enums here when they are in transit.
7408 // Note that we cannot afford to hit MemberLookup in this case because
7409 // it will fail to find any members at all
7413 if (expr is TypeExpr){
7414 expr_type = ((TypeExpr) expr).ResolveType (ec);
7416 if (!ec.DeclSpace.CheckAccessLevel (expr_type)){
7417 Report.Error_T (122, loc, expr_type);
7421 if (expr_type == TypeManager.enum_type || expr_type.IsSubclassOf (TypeManager.enum_type)){
7422 Enum en = TypeManager.LookupEnum (expr_type);
7425 object value = en.LookupEnumValue (ec, Identifier, loc);
7428 ObsoleteAttribute oa = en.GetObsoleteAttribute (ec, Identifier);
7430 AttributeTester.Report_ObsoleteMessage (oa, en.GetSignatureForError (), Location);
7433 Constant c = Constantify (value, en.UnderlyingType);
7434 return new EnumConstant (c, expr_type);
7437 CheckObsoleteAttribute (expr_type);
7439 FieldInfo fi = expr_type.GetField (Identifier);
7441 ObsoleteAttribute oa = AttributeTester.GetMemberObsoleteAttribute (fi);
7443 AttributeTester.Report_ObsoleteMessage (oa, TypeManager.GetFullNameSignature (fi), Location);
7448 expr_type = expr.Type;
7450 if (expr_type.IsPointer){
7451 Error (23, "The `.' operator can not be applied to pointer operands (" +
7452 TypeManager.CSharpName (expr_type) + ")");
7456 int errors = Report.Errors;
7458 Expression member_lookup;
7459 member_lookup = MemberLookup (
7460 ec, expr_type, expr_type, Identifier, loc);
7461 if ((member_lookup == null) && (args != null)) {
7462 string lookup_id = Identifier + "!" + args.Count;
7463 member_lookup = MemberLookup (
7464 ec, expr_type, expr_type, lookup_id, loc);
7466 if (member_lookup == null) {
7467 MemberLookupFailed (
7468 ec, expr_type, expr_type, Identifier, null, loc);
7472 if (member_lookup is TypeExpr) {
7473 if (!(expr is TypeExpr) && !(expr is SimpleName)) {
7474 Error (572, "Can't reference type `" + Identifier + "' through an expression; try `" +
7475 member_lookup.Type + "' instead");
7479 return member_lookup;
7483 string full_name = expr_type + "." + Identifier;
7485 if (member_lookup is FieldExpr) {
7486 Report.Error (307, loc, "The field `{0}' cannot " +
7487 "be used with type arguments", full_name);
7489 } else if (member_lookup is EventExpr) {
7490 Report.Error (307, loc, "The event `{0}' cannot " +
7491 "be used with type arguments", full_name);
7493 } else if (member_lookup is PropertyExpr) {
7494 Report.Error (307, loc, "The property `{0}' cannot " +
7495 "be used with type arguments", full_name);
7500 member_lookup = ResolveMemberAccess (ec, member_lookup, expr, loc, original);
7501 if (member_lookup == null)
7505 MethodGroupExpr mg = member_lookup as MethodGroupExpr;
7507 throw new InternalErrorException ();
7509 return mg.ResolveGeneric (ec, args);
7512 // The following DoResolve/DoResolveLValue will do the definite assignment
7515 if (right_side != null)
7516 member_lookup = member_lookup.DoResolveLValue (ec, right_side);
7518 member_lookup = member_lookup.DoResolve (ec);
7520 return member_lookup;
7523 public override Expression DoResolve (EmitContext ec)
7525 return DoResolve (ec, null, ResolveFlags.VariableOrValue |
7526 ResolveFlags.SimpleName | ResolveFlags.Type);
7529 public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
7531 return DoResolve (ec, right_side, ResolveFlags.VariableOrValue |
7532 ResolveFlags.SimpleName | ResolveFlags.Type);
7535 public override Expression ResolveAsTypeStep (EmitContext ec)
7537 string fname = null;
7538 MemberAccess full_expr = this;
7539 while (full_expr != null) {
7541 fname = String.Concat (full_expr.Identifier, ".", fname);
7543 fname = full_expr.Identifier;
7545 if (full_expr.Expr is SimpleName) {
7546 string full_name = String.Concat (((SimpleName) full_expr.Expr).Name, ".", fname);
7547 Type fully_qualified = ec.DeclSpace.FindType (loc, full_name);
7548 if (fully_qualified != null)
7549 return new TypeExpression (fully_qualified, loc);
7552 full_expr = full_expr.Expr as MemberAccess;
7555 Expression new_expr = expr.ResolveAsTypeStep (ec);
7557 if (new_expr == null)
7560 if (new_expr is SimpleName){
7561 SimpleName child_expr = (SimpleName) new_expr;
7563 new_expr = new SimpleName (child_expr.Name, Identifier, loc);
7565 return new_expr.ResolveAsTypeStep (ec);
7568 Type expr_type = ((TypeExpr) new_expr).ResolveType (ec);
7570 if (expr_type.IsPointer){
7571 Error (23, "The `.' operator can not be applied to pointer operands (" +
7572 TypeManager.CSharpName (expr_type) + ")");
7576 Expression member_lookup;
7579 lookup_id = Identifier + "!" + args.Count;
7581 lookup_id = Identifier;
7582 member_lookup = MemberLookupFinal (
7583 ec, expr_type, expr_type, lookup_id, loc);
7584 if (member_lookup == null)
7587 TypeExpr texpr = member_lookup as TypeExpr;
7591 Type t = texpr.ResolveType (ec);
7595 if (TypeManager.HasGenericArguments (expr_type)) {
7596 Type[] decl_args = TypeManager.GetTypeArguments (expr_type);
7598 TypeArguments new_args = new TypeArguments (loc);
7599 foreach (Type decl in decl_args)
7600 new_args.Add (new TypeExpression (decl, loc));
7603 new_args.Add (args);
7609 ConstructedType ctype = new ConstructedType (t, args, loc);
7610 return ctype.ResolveAsTypeStep (ec);
7616 public override void Emit (EmitContext ec)
7618 throw new Exception ("Should not happen");
7621 public override string ToString ()
7624 return expr + "." + Identifier + "!" + args.Count;
7626 return expr + "." + Identifier;
7631 /// Implements checked expressions
7633 public class CheckedExpr : Expression {
7635 public Expression Expr;
7637 public CheckedExpr (Expression e, Location l)
7643 public override Expression DoResolve (EmitContext ec)
7645 bool last_check = ec.CheckState;
7646 bool last_const_check = ec.ConstantCheckState;
7648 ec.CheckState = true;
7649 ec.ConstantCheckState = true;
7650 Expr = Expr.Resolve (ec);
7651 ec.CheckState = last_check;
7652 ec.ConstantCheckState = last_const_check;
7657 if (Expr is Constant)
7660 eclass = Expr.eclass;
7665 public override void Emit (EmitContext ec)
7667 bool last_check = ec.CheckState;
7668 bool last_const_check = ec.ConstantCheckState;
7670 ec.CheckState = true;
7671 ec.ConstantCheckState = true;
7673 ec.CheckState = last_check;
7674 ec.ConstantCheckState = last_const_check;
7680 /// Implements the unchecked expression
7682 public class UnCheckedExpr : Expression {
7684 public Expression Expr;
7686 public UnCheckedExpr (Expression e, Location l)
7692 public override Expression DoResolve (EmitContext ec)
7694 bool last_check = ec.CheckState;
7695 bool last_const_check = ec.ConstantCheckState;
7697 ec.CheckState = false;
7698 ec.ConstantCheckState = false;
7699 Expr = Expr.Resolve (ec);
7700 ec.CheckState = last_check;
7701 ec.ConstantCheckState = last_const_check;
7706 if (Expr is Constant)
7709 eclass = Expr.eclass;
7714 public override void Emit (EmitContext ec)
7716 bool last_check = ec.CheckState;
7717 bool last_const_check = ec.ConstantCheckState;
7719 ec.CheckState = false;
7720 ec.ConstantCheckState = false;
7722 ec.CheckState = last_check;
7723 ec.ConstantCheckState = last_const_check;
7729 /// An Element Access expression.
7731 /// During semantic analysis these are transformed into
7732 /// IndexerAccess, ArrayAccess or a PointerArithmetic.
7734 public class ElementAccess : Expression {
7735 public ArrayList Arguments;
7736 public Expression Expr;
7738 public ElementAccess (Expression e, ArrayList e_list, Location l)
7747 Arguments = new ArrayList ();
7748 foreach (Expression tmp in e_list)
7749 Arguments.Add (new Argument (tmp, Argument.AType.Expression));
7753 bool CommonResolve (EmitContext ec)
7755 Expr = Expr.Resolve (ec);
7760 if (Arguments == null)
7763 foreach (Argument a in Arguments){
7764 if (!a.Resolve (ec, loc))
7771 Expression MakePointerAccess ()
7775 if (t == TypeManager.void_ptr_type){
7776 Error (242, "The array index operation is not valid for void pointers");
7779 if (Arguments.Count != 1){
7780 Error (196, "A pointer must be indexed by a single value");
7785 p = new PointerArithmetic (true, Expr, ((Argument)Arguments [0]).Expr, t, loc);
7786 return new Indirection (p, loc);
7789 public override Expression DoResolve (EmitContext ec)
7791 if (!CommonResolve (ec))
7795 // We perform some simple tests, and then to "split" the emit and store
7796 // code we create an instance of a different class, and return that.
7798 // I am experimenting with this pattern.
7802 if (t == TypeManager.array_type){
7803 Report.Error (21, loc, "Cannot use indexer on System.Array");
7808 return (new ArrayAccess (this, loc)).Resolve (ec);
7809 else if (t.IsPointer)
7810 return MakePointerAccess ();
7812 return (new IndexerAccess (this, loc)).Resolve (ec);
7815 public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
7817 if (!CommonResolve (ec))
7822 return (new ArrayAccess (this, loc)).ResolveLValue (ec, right_side);
7823 else if (t.IsPointer)
7824 return MakePointerAccess ();
7826 return (new IndexerAccess (this, loc)).ResolveLValue (ec, right_side);
7829 public override void Emit (EmitContext ec)
7831 throw new Exception ("Should never be reached");
7836 /// Implements array access
7838 public class ArrayAccess : Expression, IAssignMethod, IMemoryLocation {
7840 // Points to our "data" repository
7844 LocalTemporary [] cached_locations;
7846 public ArrayAccess (ElementAccess ea_data, Location l)
7849 eclass = ExprClass.Variable;
7853 public override Expression DoResolve (EmitContext ec)
7856 ExprClass eclass = ea.Expr.eclass;
7858 // As long as the type is valid
7859 if (!(eclass == ExprClass.Variable || eclass == ExprClass.PropertyAccess ||
7860 eclass == ExprClass.Value)) {
7861 ea.Expr.Error_UnexpectedKind ("variable or value");
7866 Type t = ea.Expr.Type;
7867 if (t.GetArrayRank () != ea.Arguments.Count){
7869 "Incorrect number of indexes for array " +
7870 " expected: " + t.GetArrayRank () + " got: " +
7871 ea.Arguments.Count);
7875 type = TypeManager.GetElementType (t);
7876 if (type.IsPointer && !ec.InUnsafe){
7877 UnsafeError (ea.Location);
7881 foreach (Argument a in ea.Arguments){
7882 Type argtype = a.Type;
7884 if (argtype == TypeManager.int32_type ||
7885 argtype == TypeManager.uint32_type ||
7886 argtype == TypeManager.int64_type ||
7887 argtype == TypeManager.uint64_type)
7891 // Mhm. This is strage, because the Argument.Type is not the same as
7892 // Argument.Expr.Type: the value changes depending on the ref/out setting.
7894 // Wonder if I will run into trouble for this.
7896 a.Expr = ExpressionToArrayArgument (ec, a.Expr, ea.Location);
7901 eclass = ExprClass.Variable;
7907 /// Emits the right opcode to load an object of Type `t'
7908 /// from an array of T
7910 static public void EmitLoadOpcode (ILGenerator ig, Type type)
7912 if (type == TypeManager.byte_type || type == TypeManager.bool_type)
7913 ig.Emit (OpCodes.Ldelem_U1);
7914 else if (type == TypeManager.sbyte_type)
7915 ig.Emit (OpCodes.Ldelem_I1);
7916 else if (type == TypeManager.short_type)
7917 ig.Emit (OpCodes.Ldelem_I2);
7918 else if (type == TypeManager.ushort_type || type == TypeManager.char_type)
7919 ig.Emit (OpCodes.Ldelem_U2);
7920 else if (type == TypeManager.int32_type)
7921 ig.Emit (OpCodes.Ldelem_I4);
7922 else if (type == TypeManager.uint32_type)
7923 ig.Emit (OpCodes.Ldelem_U4);
7924 else if (type == TypeManager.uint64_type)
7925 ig.Emit (OpCodes.Ldelem_I8);
7926 else if (type == TypeManager.int64_type)
7927 ig.Emit (OpCodes.Ldelem_I8);
7928 else if (type == TypeManager.float_type)
7929 ig.Emit (OpCodes.Ldelem_R4);
7930 else if (type == TypeManager.double_type)
7931 ig.Emit (OpCodes.Ldelem_R8);
7932 else if (type == TypeManager.intptr_type)
7933 ig.Emit (OpCodes.Ldelem_I);
7934 else if (TypeManager.IsEnumType (type)){
7935 EmitLoadOpcode (ig, TypeManager.EnumToUnderlying (type));
7936 } else if (type.IsValueType){
7937 ig.Emit (OpCodes.Ldelema, type);
7938 ig.Emit (OpCodes.Ldobj, type);
7939 } else if (type.IsGenericParameter)
7940 ig.Emit (OpCodes.Ldelem_Any, type);
7942 ig.Emit (OpCodes.Ldelem_Ref);
7946 /// Emits the right opcode to store an object of Type `t'
7947 /// from an array of T.
7949 static public void EmitStoreOpcode (ILGenerator ig, Type t)
7951 bool is_stobj, has_type_arg;
7952 OpCode op = GetStoreOpcode (t, out is_stobj, out has_type_arg);
7960 /// Returns the right opcode to store an object of Type `t'
7961 /// from an array of T.
7963 static public OpCode GetStoreOpcode (Type t, out bool is_stobj, out bool has_type_arg)
7965 //Console.WriteLine (new System.Diagnostics.StackTrace ());
7966 has_type_arg = false; is_stobj = false;
7967 t = TypeManager.TypeToCoreType (t);
7968 if (TypeManager.IsEnumType (t) && t != TypeManager.enum_type)
7969 t = TypeManager.EnumToUnderlying (t);
7970 if (t == TypeManager.byte_type || t == TypeManager.sbyte_type ||
7971 t == TypeManager.bool_type)
7972 return OpCodes.Stelem_I1;
7973 else if (t == TypeManager.short_type || t == TypeManager.ushort_type ||
7974 t == TypeManager.char_type)
7975 return OpCodes.Stelem_I2;
7976 else if (t == TypeManager.int32_type || t == TypeManager.uint32_type)
7977 return OpCodes.Stelem_I4;
7978 else if (t == TypeManager.int64_type || t == TypeManager.uint64_type)
7979 return OpCodes.Stelem_I8;
7980 else if (t == TypeManager.float_type)
7981 return OpCodes.Stelem_R4;
7982 else if (t == TypeManager.double_type)
7983 return OpCodes.Stelem_R8;
7984 else if (t == TypeManager.intptr_type) {
7985 has_type_arg = true;
7987 return OpCodes.Stobj;
7988 } else if (t.IsValueType) {
7989 has_type_arg = true;
7991 return OpCodes.Stobj;
7992 } else if (t.IsGenericParameter) {
7993 has_type_arg = true;
7994 return OpCodes.Stelem_Any;
7996 return OpCodes.Stelem_Ref;
7999 MethodInfo FetchGetMethod ()
8001 ModuleBuilder mb = CodeGen.Module.Builder;
8002 int arg_count = ea.Arguments.Count;
8003 Type [] args = new Type [arg_count];
8006 for (int i = 0; i < arg_count; i++){
8007 //args [i++] = a.Type;
8008 args [i] = TypeManager.int32_type;
8011 get = mb.GetArrayMethod (
8012 ea.Expr.Type, "Get",
8013 CallingConventions.HasThis |
8014 CallingConventions.Standard,
8020 MethodInfo FetchAddressMethod ()
8022 ModuleBuilder mb = CodeGen.Module.Builder;
8023 int arg_count = ea.Arguments.Count;
8024 Type [] args = new Type [arg_count];
8028 ret_type = TypeManager.GetReferenceType (type);
8030 for (int i = 0; i < arg_count; i++){
8031 //args [i++] = a.Type;
8032 args [i] = TypeManager.int32_type;
8035 address = mb.GetArrayMethod (
8036 ea.Expr.Type, "Address",
8037 CallingConventions.HasThis |
8038 CallingConventions.Standard,
8045 // Load the array arguments into the stack.
8047 // If we have been requested to cache the values (cached_locations array
8048 // initialized), then load the arguments the first time and store them
8049 // in locals. otherwise load from local variables.
8051 void LoadArrayAndArguments (EmitContext ec)
8053 ILGenerator ig = ec.ig;
8055 if (cached_locations == null){
8057 foreach (Argument a in ea.Arguments){
8058 Type argtype = a.Expr.Type;
8062 if (argtype == TypeManager.int64_type)
8063 ig.Emit (OpCodes.Conv_Ovf_I);
8064 else if (argtype == TypeManager.uint64_type)
8065 ig.Emit (OpCodes.Conv_Ovf_I_Un);
8070 if (cached_locations [0] == null){
8071 cached_locations [0] = new LocalTemporary (ec, ea.Expr.Type);
8073 ig.Emit (OpCodes.Dup);
8074 cached_locations [0].Store (ec);
8078 foreach (Argument a in ea.Arguments){
8079 Type argtype = a.Expr.Type;
8081 cached_locations [j] = new LocalTemporary (ec, TypeManager.intptr_type /* a.Expr.Type */);
8083 if (argtype == TypeManager.int64_type)
8084 ig.Emit (OpCodes.Conv_Ovf_I);
8085 else if (argtype == TypeManager.uint64_type)
8086 ig.Emit (OpCodes.Conv_Ovf_I_Un);
8088 ig.Emit (OpCodes.Dup);
8089 cached_locations [j].Store (ec);
8095 foreach (LocalTemporary lt in cached_locations)
8099 public new void CacheTemporaries (EmitContext ec)
8101 cached_locations = new LocalTemporary [ea.Arguments.Count + 1];
8104 public override void Emit (EmitContext ec)
8106 int rank = ea.Expr.Type.GetArrayRank ();
8107 ILGenerator ig = ec.ig;
8109 LoadArrayAndArguments (ec);
8112 EmitLoadOpcode (ig, type);
8116 method = FetchGetMethod ();
8117 ig.Emit (OpCodes.Call, method);
8121 public void EmitAssign (EmitContext ec, Expression source)
8123 int rank = ea.Expr.Type.GetArrayRank ();
8124 ILGenerator ig = ec.ig;
8125 Type t = source.Type;
8127 LoadArrayAndArguments (ec);
8130 // The stobj opcode used by value types will need
8131 // an address on the stack, not really an array/array
8135 if (t == TypeManager.enum_type || t == TypeManager.decimal_type ||
8136 (t.IsSubclassOf (TypeManager.value_type) && !TypeManager.IsEnumType (t) && !TypeManager.IsBuiltinType (t)))
8137 ig.Emit (OpCodes.Ldelema, t);
8143 EmitStoreOpcode (ig, t);
8145 ModuleBuilder mb = CodeGen.Module.Builder;
8146 int arg_count = ea.Arguments.Count;
8147 Type [] args = new Type [arg_count + 1];
8150 for (int i = 0; i < arg_count; i++){
8151 //args [i++] = a.Type;
8152 args [i] = TypeManager.int32_type;
8155 args [arg_count] = type;
8157 set = mb.GetArrayMethod (
8158 ea.Expr.Type, "Set",
8159 CallingConventions.HasThis |
8160 CallingConventions.Standard,
8161 TypeManager.void_type, args);
8163 ig.Emit (OpCodes.Call, set);
8167 public void AddressOf (EmitContext ec, AddressOp mode)
8169 int rank = ea.Expr.Type.GetArrayRank ();
8170 ILGenerator ig = ec.ig;
8172 LoadArrayAndArguments (ec);
8175 ig.Emit (OpCodes.Ldelema, type);
8177 MethodInfo address = FetchAddressMethod ();
8178 ig.Emit (OpCodes.Call, address);
8185 public ArrayList Properties;
8186 static Hashtable map;
8188 public struct Indexer {
8189 public readonly Type Type;
8190 public readonly MethodInfo Getter, Setter;
8192 public Indexer (Type type, MethodInfo get, MethodInfo set)
8202 map = new Hashtable ();
8207 Properties = new ArrayList ();
8210 void Append (MemberInfo [] mi)
8212 foreach (PropertyInfo property in mi){
8213 MethodInfo get, set;
8215 get = property.GetGetMethod (true);
8216 set = property.GetSetMethod (true);
8217 Properties.Add (new Indexer (property.PropertyType, get, set));
8221 static private MemberInfo [] GetIndexersForTypeOrInterface (Type caller_type, Type lookup_type)
8223 string p_name = TypeManager.IndexerPropertyName (lookup_type);
8225 MemberInfo [] mi = TypeManager.MemberLookup (
8226 caller_type, caller_type, lookup_type, MemberTypes.Property,
8227 BindingFlags.Public | BindingFlags.Instance |
8228 BindingFlags.DeclaredOnly, p_name, null);
8230 if (mi == null || mi.Length == 0)
8236 static public Indexers GetIndexersForType (Type caller_type, Type lookup_type, Location loc)
8238 Indexers ix = (Indexers) map [lookup_type];
8243 Type copy = lookup_type;
8244 while (copy != TypeManager.object_type && copy != null){
8245 MemberInfo [] mi = GetIndexersForTypeOrInterface (caller_type, copy);
8249 ix = new Indexers ();
8254 copy = copy.BaseType;
8257 if (!lookup_type.IsInterface)
8260 TypeExpr [] ifaces = TypeManager.GetInterfaces (lookup_type);
8261 if (ifaces != null) {
8262 foreach (TypeExpr iface in ifaces) {
8263 Type itype = iface.Type;
8264 MemberInfo [] mi = GetIndexersForTypeOrInterface (caller_type, itype);
8267 ix = new Indexers ();
8279 /// Expressions that represent an indexer call.
8281 public class IndexerAccess : Expression, IAssignMethod {
8283 // Points to our "data" repository
8285 MethodInfo get, set;
8286 ArrayList set_arguments;
8287 bool is_base_indexer;
8289 protected Type indexer_type;
8290 protected Type current_type;
8291 protected Expression instance_expr;
8292 protected ArrayList arguments;
8294 public IndexerAccess (ElementAccess ea, Location loc)
8295 : this (ea.Expr, false, loc)
8297 this.arguments = ea.Arguments;
8300 protected IndexerAccess (Expression instance_expr, bool is_base_indexer,
8303 this.instance_expr = instance_expr;
8304 this.is_base_indexer = is_base_indexer;
8305 this.eclass = ExprClass.Value;
8309 protected virtual bool CommonResolve (EmitContext ec)
8311 indexer_type = instance_expr.Type;
8312 current_type = ec.ContainerType;
8317 public override Expression DoResolve (EmitContext ec)
8319 ArrayList AllGetters = new ArrayList();
8320 if (!CommonResolve (ec))
8324 // Step 1: Query for all `Item' *properties*. Notice
8325 // that the actual methods are pointed from here.
8327 // This is a group of properties, piles of them.
8329 bool found_any = false, found_any_getters = false;
8330 Type lookup_type = indexer_type;
8333 ilist = Indexers.GetIndexersForType (current_type, lookup_type, loc);
8334 if (ilist != null) {
8336 if (ilist.Properties != null) {
8337 foreach (Indexers.Indexer ix in ilist.Properties) {
8338 if (ix.Getter != null)
8339 AllGetters.Add(ix.Getter);
8344 if (AllGetters.Count > 0) {
8345 found_any_getters = true;
8346 get = (MethodInfo) Invocation.OverloadResolve (
8347 ec, new MethodGroupExpr (AllGetters, loc),
8348 arguments, false, loc);
8352 Report.Error (21, loc,
8353 "Type `" + TypeManager.CSharpName (indexer_type) +
8354 "' does not have any indexers defined");
8358 if (!found_any_getters) {
8359 Error (154, "indexer can not be used in this context, because " +
8360 "it lacks a `get' accessor");
8365 Error (1501, "No Overload for method `this' takes `" +
8366 arguments.Count + "' arguments");
8371 // Only base will allow this invocation to happen.
8373 if (get.IsAbstract && this is BaseIndexerAccess){
8374 Report.Error (205, loc, "Cannot call an abstract base indexer: " + Invocation.FullMethodDesc (get));
8378 type = get.ReturnType;
8379 if (type.IsPointer && !ec.InUnsafe){
8384 eclass = ExprClass.IndexerAccess;
8388 public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
8390 ArrayList AllSetters = new ArrayList();
8391 if (!CommonResolve (ec))
8394 bool found_any = false, found_any_setters = false;
8396 Indexers ilist = Indexers.GetIndexersForType (current_type, indexer_type, loc);
8397 if (ilist != null) {
8399 if (ilist.Properties != null) {
8400 foreach (Indexers.Indexer ix in ilist.Properties) {
8401 if (ix.Setter != null)
8402 AllSetters.Add(ix.Setter);
8406 if (AllSetters.Count > 0) {
8407 found_any_setters = true;
8408 set_arguments = (ArrayList) arguments.Clone ();
8409 set_arguments.Add (new Argument (right_side, Argument.AType.Expression));
8410 set = (MethodInfo) Invocation.OverloadResolve (
8411 ec, new MethodGroupExpr (AllSetters, loc),
8412 set_arguments, false, loc);
8416 Report.Error (21, loc,
8417 "Type `" + TypeManager.CSharpName (indexer_type) +
8418 "' does not have any indexers defined");
8422 if (!found_any_setters) {
8423 Error (154, "indexer can not be used in this context, because " +
8424 "it lacks a `set' accessor");
8429 Error (1501, "No Overload for method `this' takes `" +
8430 arguments.Count + "' arguments");
8435 // Only base will allow this invocation to happen.
8437 if (set.IsAbstract && this is BaseIndexerAccess){
8438 Report.Error (205, loc, "Cannot call an abstract base indexer: " + Invocation.FullMethodDesc (set));
8443 // Now look for the actual match in the list of indexers to set our "return" type
8445 type = TypeManager.void_type; // default value
8446 foreach (Indexers.Indexer ix in ilist.Properties){
8447 if (ix.Setter == set){
8453 eclass = ExprClass.IndexerAccess;
8457 public override void Emit (EmitContext ec)
8459 Invocation.EmitCall (ec, is_base_indexer, false, instance_expr, get, arguments, loc);
8463 // source is ignored, because we already have a copy of it from the
8464 // LValue resolution and we have already constructed a pre-cached
8465 // version of the arguments (ea.set_arguments);
8467 public void EmitAssign (EmitContext ec, Expression source)
8469 Invocation.EmitCall (ec, is_base_indexer, false, instance_expr, set, set_arguments, loc);
8474 /// The base operator for method names
8476 public class BaseAccess : Expression {
8479 public BaseAccess (string member, Location l)
8481 this.member = member;
8485 public override Expression DoResolve (EmitContext ec)
8487 Expression c = CommonResolve (ec);
8493 // MethodGroups use this opportunity to flag an error on lacking ()
8495 if (!(c is MethodGroupExpr))
8496 return c.Resolve (ec);
8500 public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
8502 Expression c = CommonResolve (ec);
8508 // MethodGroups use this opportunity to flag an error on lacking ()
8510 if (! (c is MethodGroupExpr))
8511 return c.DoResolveLValue (ec, right_side);
8516 Expression CommonResolve (EmitContext ec)
8518 Expression member_lookup;
8519 Type current_type = ec.ContainerType;
8520 Type base_type = current_type.BaseType;
8524 Error (1511, "Keyword base is not allowed in static method");
8528 if (ec.IsFieldInitializer){
8529 Error (1512, "Keyword base is not available in the current context");
8533 member_lookup = MemberLookup (ec, ec.ContainerType, null, base_type,
8534 member, AllMemberTypes, AllBindingFlags,
8536 if (member_lookup == null) {
8537 MemberLookupFailed (
8538 ec, base_type, base_type, member, null, loc);
8545 left = new TypeExpression (base_type, loc);
8547 left = ec.GetThis (loc);
8549 e = MemberAccess.ResolveMemberAccess (ec, member_lookup, left, loc, null);
8551 if (e is PropertyExpr){
8552 PropertyExpr pe = (PropertyExpr) e;
8560 public override void Emit (EmitContext ec)
8562 throw new Exception ("Should never be called");
8567 /// The base indexer operator
8569 public class BaseIndexerAccess : IndexerAccess {
8570 public BaseIndexerAccess (ArrayList args, Location loc)
8571 : base (null, true, loc)
8573 arguments = new ArrayList ();
8574 foreach (Expression tmp in args)
8575 arguments.Add (new Argument (tmp, Argument.AType.Expression));
8578 protected override bool CommonResolve (EmitContext ec)
8580 instance_expr = ec.GetThis (loc);
8582 current_type = ec.ContainerType.BaseType;
8583 indexer_type = current_type;
8585 foreach (Argument a in arguments){
8586 if (!a.Resolve (ec, loc))
8595 /// This class exists solely to pass the Type around and to be a dummy
8596 /// that can be passed to the conversion functions (this is used by
8597 /// foreach implementation to typecast the object return value from
8598 /// get_Current into the proper type. All code has been generated and
8599 /// we only care about the side effect conversions to be performed
8601 /// This is also now used as a placeholder where a no-action expression
8602 /// is needed (the `New' class).
8604 public class EmptyExpression : Expression {
8605 public EmptyExpression ()
8607 type = TypeManager.object_type;
8608 eclass = ExprClass.Value;
8609 loc = Location.Null;
8612 public EmptyExpression (Type t)
8615 eclass = ExprClass.Value;
8616 loc = Location.Null;
8619 public override Expression DoResolve (EmitContext ec)
8624 public override void Emit (EmitContext ec)
8626 // nothing, as we only exist to not do anything.
8630 // This is just because we might want to reuse this bad boy
8631 // instead of creating gazillions of EmptyExpressions.
8632 // (CanImplicitConversion uses it)
8634 public void SetType (Type t)
8640 public class UserCast : Expression {
8644 public UserCast (MethodInfo method, Expression source, Location l)
8646 this.method = method;
8647 this.source = source;
8648 type = method.ReturnType;
8649 eclass = ExprClass.Value;
8653 public override Expression DoResolve (EmitContext ec)
8656 // We are born fully resolved
8661 public override void Emit (EmitContext ec)
8663 ILGenerator ig = ec.ig;
8667 if (method is MethodInfo)
8668 ig.Emit (OpCodes.Call, (MethodInfo) method);
8670 ig.Emit (OpCodes.Call, (ConstructorInfo) method);
8676 // This class is used to "construct" the type during a typecast
8677 // operation. Since the Type.GetType class in .NET can parse
8678 // the type specification, we just use this to construct the type
8679 // one bit at a time.
8681 public class ComposedCast : TypeExpr {
8685 public ComposedCast (Expression left, string dim, Location l)
8692 public override TypeExpr DoResolveAsTypeStep (EmitContext ec)
8694 Type ltype = ec.DeclSpace.ResolveType (left, false, loc);
8698 if ((ltype == TypeManager.void_type) && (dim != "*")) {
8699 Report.Error (1547, Location,
8700 "Keyword 'void' cannot be used in this context");
8705 while ((pos < dim.Length) && (dim [pos] == '[')) {
8708 if (dim [pos] == ']') {
8709 ltype = ltype.MakeArrayType ();
8712 if (pos < dim.Length)
8716 eclass = ExprClass.Type;
8721 while (dim [pos] == ',') {
8725 if ((dim [pos] != ']') || (pos != dim.Length-1))
8728 type = ltype.MakeArrayType (rank + 1);
8729 eclass = ExprClass.Type;
8734 // ltype.Fullname is already fully qualified, so we can skip
8735 // a lot of probes, and go directly to TypeManager.LookupType
8737 string fname = ltype.FullName != null ? ltype.FullName : ltype.Name;
8738 string cname = fname + dim;
8739 type = TypeManager.LookupTypeDirect (cname);
8742 // For arrays of enumerations we are having a problem
8743 // with the direct lookup. Need to investigate.
8745 // For now, fall back to the full lookup in that case.
8747 TypeExpr texpr = RootContext.LookupType (
8748 ec.DeclSpace, cname, false, loc);
8753 type = texpr.ResolveType (ec);
8758 if (!ec.ResolvingTypeTree){
8760 // If the above flag is set, this is being invoked from the ResolveType function.
8761 // Upper layers take care of the type validity in this context.
8763 if (!ec.InUnsafe && type.IsPointer){
8769 eclass = ExprClass.Type;
8773 public override string Name {
8781 // This class is used to represent the address of an array, used
8782 // only by the Fixed statement, this is like the C "&a [0]" construct.
8784 public class ArrayPtr : Expression {
8787 public ArrayPtr (Expression array, Location l)
8789 Type array_type = TypeManager.GetElementType (array.Type);
8793 type = TypeManager.GetPointerType (array_type);
8794 eclass = ExprClass.Value;
8798 public override void Emit (EmitContext ec)
8800 ILGenerator ig = ec.ig;
8803 IntLiteral.EmitInt (ig, 0);
8804 ig.Emit (OpCodes.Ldelema, TypeManager.GetElementType (array.Type));
8807 public override Expression DoResolve (EmitContext ec)
8810 // We are born fully resolved
8817 // Used by the fixed statement
8819 public class StringPtr : Expression {
8822 public StringPtr (LocalBuilder b, Location l)
8825 eclass = ExprClass.Value;
8826 type = TypeManager.char_ptr_type;
8830 public override Expression DoResolve (EmitContext ec)
8832 // This should never be invoked, we are born in fully
8833 // initialized state.
8838 public override void Emit (EmitContext ec)
8840 ILGenerator ig = ec.ig;
8842 ig.Emit (OpCodes.Ldloc, b);
8843 ig.Emit (OpCodes.Conv_I);
8844 ig.Emit (OpCodes.Call, TypeManager.int_get_offset_to_string_data);
8845 ig.Emit (OpCodes.Add);
8850 // Implements the `stackalloc' keyword
8852 public class StackAlloc : Expression {
8857 public StackAlloc (Expression type, Expression count, Location l)
8864 public override Expression DoResolve (EmitContext ec)
8866 count = count.Resolve (ec);
8870 if (count.Type != TypeManager.int32_type){
8871 count = Convert.ImplicitConversionRequired (ec, count, TypeManager.int32_type, loc);
8876 if (ec.CurrentBranching.InCatch () ||
8877 ec.CurrentBranching.InFinally (true)) {
8879 "stackalloc can not be used in a catch or finally block");
8883 otype = ec.DeclSpace.ResolveType (t, false, loc);
8888 if (!TypeManager.VerifyUnManaged (otype, loc))
8891 type = TypeManager.GetPointerType (otype);
8892 eclass = ExprClass.Value;
8897 public override void Emit (EmitContext ec)
8899 int size = GetTypeSize (otype);
8900 ILGenerator ig = ec.ig;
8903 ig.Emit (OpCodes.Sizeof, otype);
8905 IntConstant.EmitInt (ig, size);
8907 ig.Emit (OpCodes.Mul);
8908 ig.Emit (OpCodes.Localloc);