//
// ecore.cs: Core of the Expression representation for the intermediate tree.
//
// Author:
// Miguel de Icaza (miguel@ximian.com)
// Marek Safar (marek.safar@seznam.cz)
//
// Copyright 2001, 2002, 2003 Ximian, Inc.
// Copyright 2003-2008 Novell, Inc.
//
//
using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Reflection;
using System.Reflection.Emit;
using System.Text;
using SLE = System.Linq.Expressions;
using System.Linq;
namespace Mono.CSharp {
///
/// The ExprClass class contains the is used to pass the
/// classification of an expression (value, variable, namespace,
/// type, method group, property access, event access, indexer access,
/// nothing).
///
public enum ExprClass : byte {
Unresolved = 0,
Value,
Variable,
Namespace,
Type,
TypeParameter,
MethodGroup,
PropertyAccess,
EventAccess,
IndexerAccess,
Nothing,
}
///
/// This is used to tell Resolve in which types of expressions we're
/// interested.
///
[Flags]
public enum ResolveFlags {
// Returns Value, Variable, PropertyAccess, EventAccess or IndexerAccess.
VariableOrValue = 1,
// Returns a type expression.
Type = 1 << 1,
// Returns a method group.
MethodGroup = 1 << 2,
TypeParameter = 1 << 3,
// Mask of all the expression class flags.
MaskExprClass = VariableOrValue | Type | MethodGroup | TypeParameter,
}
//
// This is just as a hint to AddressOf of what will be done with the
// address.
[Flags]
public enum AddressOp {
Store = 1,
Load = 2,
LoadStore = 3
};
///
/// This interface is implemented by variables
///
public interface IMemoryLocation {
///
/// The AddressOf method should generate code that loads
/// the address of the object and leaves it on the stack.
///
/// The `mode' argument is used to notify the expression
/// of whether this will be used to read from the address or
/// write to the address.
///
/// This is just a hint that can be used to provide good error
/// reporting, and should have no other side effects.
///
void AddressOf (EmitContext ec, AddressOp mode);
}
//
// An expressions resolved as a direct variable reference
//
public interface IVariableReference : IFixedExpression
{
bool IsHoisted { get; }
string Name { get; }
VariableInfo VariableInfo { get; }
void SetHasAddressTaken ();
}
//
// Implemented by an expression which could be or is always
// fixed
//
public interface IFixedExpression
{
bool IsFixed { get; }
}
///
/// Base class for expressions
///
public abstract class Expression {
public ExprClass eclass;
protected TypeSpec type;
protected Location loc;
public TypeSpec Type {
get { return type; }
set { type = value; }
}
public virtual Location Location {
get { return loc; }
}
// Not nice but we have broken hierarchy.
public virtual void CheckMarshalByRefAccess (ResolveContext ec)
{
}
public virtual string GetSignatureForError ()
{
return type.GetDefinition ().GetSignatureForError ();
}
public static bool IsMemberAccessible (TypeSpec invocation_type, MemberSpec mi, out bool must_do_cs1540_check)
{
var ma = mi.Modifiers & Modifiers.AccessibilityMask;
must_do_cs1540_check = false; // by default we do not check for this
if (ma == Modifiers.PUBLIC)
return true;
//
// If only accessible to the current class or children
//
if (ma == Modifiers.PRIVATE)
return invocation_type.MemberDefinition == mi.DeclaringType.MemberDefinition ||
TypeManager.IsNestedChildOf (invocation_type, mi.DeclaringType);
if ((ma & Modifiers.INTERNAL) != 0) {
var b = TypeManager.IsThisOrFriendAssembly (invocation_type == InternalType.FakeInternalType ?
CodeGen.Assembly.Builder : invocation_type.Assembly, mi.DeclaringType.Assembly);
if (b || ma == Modifiers.INTERNAL)
return b;
}
// Family and FamANDAssem require that we derive.
// FamORAssem requires that we derive if in different assemblies.
if (!TypeManager.IsNestedFamilyAccessible (invocation_type, mi.DeclaringType))
return false;
if (!TypeManager.IsNestedChildOf (invocation_type, mi.DeclaringType))
must_do_cs1540_check = true;
return true;
}
public virtual bool IsNull {
get {
return false;
}
}
///
/// Performs semantic analysis on the Expression
///
///
///
/// The Resolve method is invoked to perform the semantic analysis
/// on the node.
///
/// The return value is an expression (it can be the
/// same expression in some cases) or a new
/// expression that better represents this node.
///
/// For example, optimizations of Unary (LiteralInt)
/// would return a new LiteralInt with a negated
/// value.
///
/// If there is an error during semantic analysis,
/// then an error should be reported (using Report)
/// and a null value should be returned.
///
/// There are two side effects expected from calling
/// Resolve(): the the field variable "eclass" should
/// be set to any value of the enumeration
/// `ExprClass' and the type variable should be set
/// to a valid type (this is the type of the
/// expression).
///
protected abstract Expression DoResolve (ResolveContext rc);
public virtual Expression DoResolveLValue (ResolveContext rc, Expression right_side)
{
return null;
}
//
// This is used if the expression should be resolved as a type or namespace name.
// the default implementation fails.
//
public virtual FullNamedExpression ResolveAsTypeStep (IMemberContext rc, bool silent)
{
if (!silent) {
ResolveContext ec = new ResolveContext (rc);
Expression e = Resolve (ec);
if (e != null)
e.Error_UnexpectedKind (ec, ResolveFlags.Type, loc);
}
return null;
}
//
// C# 3.0 introduced contextual keywords (var) which behaves like a type if type with
// same name exists or as a keyword when no type was found
//
public virtual TypeExpr ResolveAsContextualType (IMemberContext rc, bool silent)
{
return ResolveAsTypeTerminal (rc, silent);
}
//
// This is used to resolve the expression as a type, a null
// value will be returned if the expression is not a type
// reference
//
public virtual TypeExpr ResolveAsTypeTerminal (IMemberContext ec , bool silent)
{
int errors = ec.Compiler.Report.Errors;
FullNamedExpression fne = ResolveAsTypeStep (ec, silent);
if (fne == null)
return null;
TypeExpr te = fne as TypeExpr;
if (te == null) {
if (!silent && errors == ec.Compiler.Report.Errors)
fne.Error_UnexpectedKind (ec.Compiler.Report, null, "type", loc);
return null;
}
if (!te.CheckAccessLevel (ec)) {
ec.Compiler.Report.SymbolRelatedToPreviousError (te.Type);
ErrorIsInaccesible (loc, TypeManager.CSharpName (te.Type), ec.Compiler.Report);
}
te.loc = loc;
//
// Obsolete checks cannot be done when resolving base context as they
// require type dependecies to be set but we are just resolving them
//
if (!silent && !(ec is TypeContainer.BaseContext)) {
ObsoleteAttribute obsolete_attr = te.Type.GetAttributeObsolete ();
if (obsolete_attr != null && !ec.IsObsolete) {
AttributeTester.Report_ObsoleteMessage (obsolete_attr, te.GetSignatureForError (), Location, ec.Compiler.Report);
}
}
return te;
}
public static void ErrorIsInaccesible (Location loc, string name, Report Report)
{
Report.Error (122, loc, "`{0}' is inaccessible due to its protection level", name);
}
protected static void Error_CannotAccessProtected (ResolveContext ec, Location loc, MemberSpec m, TypeSpec qualifier, TypeSpec container)
{
ec.Report.Error (1540, loc, "Cannot access protected member `{0}' via a qualifier of type `{1}'."
+ " The qualifier must be of type `{2}' or derived from it",
m.GetSignatureForError (),
TypeManager.CSharpName (qualifier),
TypeManager.CSharpName (container));
}
public void Error_ExpressionMustBeConstant (ResolveContext rc, Location loc, string e_name)
{
rc.Report.Error (133, loc, "The expression being assigned to `{0}' must be constant", e_name);
}
public void Error_ConstantCanBeInitializedWithNullOnly (ResolveContext rc, TypeSpec type, Location loc, string name)
{
rc.Report.Error (134, loc, "A constant `{0}' of reference type `{1}' can only be initialized with null",
name, TypeManager.CSharpName (type));
}
public static void Error_InvalidExpressionStatement (Report Report, Location loc)
{
Report.Error (201, loc, "Only assignment, call, increment, decrement, and new object " +
"expressions can be used as a statement");
}
public void Error_InvalidExpressionStatement (BlockContext ec)
{
Error_InvalidExpressionStatement (ec.Report, loc);
}
public static void Error_VoidInvalidInTheContext (Location loc, Report Report)
{
Report.Error (1547, loc, "Keyword `void' cannot be used in this context");
}
public virtual void Error_ValueCannotBeConverted (ResolveContext ec, Location loc, TypeSpec target, bool expl)
{
Error_ValueCannotBeConvertedCore (ec, loc, target, expl);
}
protected void Error_ValueCannotBeConvertedCore (ResolveContext ec, Location loc, TypeSpec target, bool expl)
{
// The error was already reported as CS1660
if (type == InternalType.AnonymousMethod)
return;
/*
if (TypeManager.IsGenericParameter (Type) && TypeManager.IsGenericParameter (target) && type.Name == target.Name) {
string sig1 = type.DeclaringMethod == null ?
TypeManager.CSharpName (type.DeclaringType) :
TypeManager.CSharpSignature (type.DeclaringMethod);
string sig2 = target.DeclaringMethod == null ?
TypeManager.CSharpName (target.DeclaringType) :
TypeManager.CSharpSignature (target.DeclaringMethod);
ec.Report.ExtraInformation (loc,
String.Format (
"The generic parameter `{0}' of `{1}' cannot be converted to the generic parameter `{0}' of `{2}' (in the previous ",
Type.Name, sig1, sig2));
} else if (Type.MetaInfo.FullName == target.MetaInfo.FullName) {
ec.Report.ExtraInformation (loc,
String.Format (
"The type `{0}' has two conflicting definitions, one comes from `{1}' and the other from `{2}' (in the previous ",
Type.MetaInfo.FullName, Type.Assembly.FullName, target.Assembly.FullName));
}
*/
if (expl) {
ec.Report.Error (30, loc, "Cannot convert type `{0}' to `{1}'",
TypeManager.CSharpName (type), TypeManager.CSharpName (target));
return;
}
ec.Report.DisableReporting ();
bool expl_exists = Convert.ExplicitConversion (ec, this, target, Location.Null) != null;
ec.Report.EnableReporting ();
if (expl_exists) {
ec.Report.Error (266, loc, "Cannot implicitly convert type `{0}' to `{1}'. " +
"An explicit conversion exists (are you missing a cast?)",
TypeManager.CSharpName (Type), TypeManager.CSharpName (target));
return;
}
ec.Report.Error (29, loc, "Cannot implicitly convert type `{0}' to `{1}'",
type.GetSignatureForError (), target.GetSignatureForError ());
}
public virtual void Error_VariableIsUsedBeforeItIsDeclared (Report Report, string name)
{
Report.Error (841, loc, "A local variable `{0}' cannot be used before it is declared", name);
}
public void Error_TypeArgumentsCannotBeUsed (Report report, Location loc, MemberSpec member, int arity)
{
// Better message for possible generic expressions
if (member != null && (member.Kind & MemberKind.GenericMask) != 0) {
report.SymbolRelatedToPreviousError (member);
if (member is TypeSpec)
member = ((TypeSpec) member).GetDefinition ();
else
member = ((MethodSpec) member).GetGenericMethodDefinition ();
string name = member.Kind == MemberKind.Method ? "method" : "type";
if (member.IsGeneric) {
report.Error (305, loc, "Using the generic {0} `{1}' requires `{2}' type argument(s)",
name, member.GetSignatureForError (), member.Arity.ToString ());
} else {
report.Error (308, loc, "The non-generic {0} `{1}' cannot be used with the type arguments",
name, member.GetSignatureForError ());
}
} else {
report.Error (307, loc, "The {0} `{1}' cannot be used with type arguments",
ExprClassName, GetSignatureForError ());
}
}
protected virtual void Error_TypeDoesNotContainDefinition (ResolveContext ec, TypeSpec type, string name)
{
Error_TypeDoesNotContainDefinition (ec, loc, type, name);
}
public static void Error_TypeDoesNotContainDefinition (ResolveContext ec, Location loc, TypeSpec type, string name)
{
ec.Report.SymbolRelatedToPreviousError (type);
ec.Report.Error (117, loc, "`{0}' does not contain a definition for `{1}'",
TypeManager.CSharpName (type), name);
}
protected static void Error_ValueAssignment (ResolveContext ec, Location loc)
{
ec.Report.Error (131, loc, "The left-hand side of an assignment must be a variable, a property or an indexer");
}
public ResolveFlags ExprClassToResolveFlags {
get {
switch (eclass) {
case ExprClass.Type:
case ExprClass.Namespace:
return ResolveFlags.Type;
case ExprClass.MethodGroup:
return ResolveFlags.MethodGroup;
case ExprClass.TypeParameter:
return ResolveFlags.TypeParameter;
case ExprClass.Value:
case ExprClass.Variable:
case ExprClass.PropertyAccess:
case ExprClass.EventAccess:
case ExprClass.IndexerAccess:
return ResolveFlags.VariableOrValue;
default:
throw new InternalErrorException (loc.ToString () + " " + GetType () + " ExprClass is Invalid after resolve");
}
}
}
///
/// Resolves an expression and performs semantic analysis on it.
///
///
///
/// Currently Resolve wraps DoResolve to perform sanity
/// checking and assertion checking on what we expect from Resolve.
///
public Expression Resolve (ResolveContext ec, ResolveFlags flags)
{
if (eclass != ExprClass.Unresolved)
return this;
Expression e;
try {
e = DoResolve (ec);
if (e == null)
return null;
if ((flags & e.ExprClassToResolveFlags) == 0) {
e.Error_UnexpectedKind (ec, flags, loc);
return null;
}
if (e.type == null)
throw new InternalErrorException ("Expression `{0}' didn't set its type in DoResolve", e.GetType ());
return e;
} catch (Exception ex) {
if (loc.IsNull || Report.DebugFlags > 0 || ex is CompletionResult || ec.Report.IsDisabled)
throw;
ec.Report.Error (584, loc, "Internal compiler error: {0}", ex.Message);
return EmptyExpression.Null;
}
}
///
/// Resolves an expression and performs semantic analysis on it.
///
public Expression Resolve (ResolveContext rc)
{
return Resolve (rc, ResolveFlags.VariableOrValue | ResolveFlags.MethodGroup);
}
///
/// Resolves an expression for LValue assignment
///
///
///
/// Currently ResolveLValue wraps DoResolveLValue to perform sanity
/// checking and assertion checking on what we expect from Resolve
///
public Expression ResolveLValue (ResolveContext ec, Expression right_side)
{
int errors = ec.Report.Errors;
bool out_access = right_side == EmptyExpression.OutAccess.Instance;
Expression e = DoResolveLValue (ec, right_side);
if (e != null && out_access && !(e is IMemoryLocation)) {
// FIXME: There's no problem with correctness, the 'Expr = null' handles that.
// Enabling this 'throw' will "only" result in deleting useless code elsewhere,
//throw new InternalErrorException ("ResolveLValue didn't return an IMemoryLocation: " +
// e.GetType () + " " + e.GetSignatureForError ());
e = null;
}
if (e == null) {
if (errors == ec.Report.Errors) {
if (out_access)
ec.Report.Error (1510, loc, "A ref or out argument must be an assignable variable");
else
Error_ValueAssignment (ec, loc);
}
return null;
}
if (e.eclass == ExprClass.Unresolved)
throw new Exception ("Expression " + e + " ExprClass is Invalid after resolve");
if ((e.type == null) && !(e is GenericTypeExpr))
throw new Exception ("Expression " + e + " did not set its type after Resolve");
return e;
}
public virtual void EncodeAttributeValue (IMemberContext rc, AttributeEncoder enc, TypeSpec targetType)
{
Attribute.Error_AttributeArgumentNotValid (rc, loc);
}
///
/// Emits the code for the expression
///
///
///
/// The Emit method is invoked to generate the code
/// for the expression.
///
public abstract void Emit (EmitContext ec);
// Emit code to branch to @target if this expression is equivalent to @on_true.
// The default implementation is to emit the value, and then emit a brtrue or brfalse.
// Subclasses can provide more efficient implementations, but those MUST be equivalent,
// including the use of conditional branches. Note also that a branch MUST be emitted
public virtual void EmitBranchable (EmitContext ec, Label target, bool on_true)
{
Emit (ec);
ec.Emit (on_true ? OpCodes.Brtrue : OpCodes.Brfalse, target);
}
// Emit this expression for its side effects, not for its value.
// The default implementation is to emit the value, and then throw it away.
// Subclasses can provide more efficient implementations, but those MUST be equivalent
public virtual void EmitSideEffect (EmitContext ec)
{
Emit (ec);
ec.Emit (OpCodes.Pop);
}
///
/// Protected constructor. Only derivate types should
/// be able to be created
///
protected Expression ()
{
}
///
/// Returns a fully formed expression after a MemberLookup
///
///
public static Expression ExprClassFromMemberInfo (TypeSpec container_type, MemberSpec spec, Location loc)
{
if (spec is EventSpec)
return new EventExpr ((EventSpec) spec, loc);
if (spec is ConstSpec)
return new ConstantExpr ((ConstSpec) spec, loc);
if (spec is FieldSpec)
return new FieldExpr ((FieldSpec) spec, loc);
if (spec is PropertySpec)
return new PropertyExpr ((PropertySpec) spec, loc);
if (spec is TypeSpec)
return new TypeExpression (((TypeSpec) spec), loc);
return null;
}
//
// FIXME: Probably implement a cache for (t,name,current_access_set)?
//
// This code could use some optimizations, but we need to do some
// measurements. For example, we could use a delegate to `flag' when
// something can not any longer be a method-group (because it is something
// else).
//
// Return values:
// If the return value is an Array, then it is an array of
// MethodBases
//
// If the return value is an MemberInfo, it is anything, but a Method
//
// null on error.
//
// FIXME: When calling MemberLookup inside an `Invocation', we should pass
// the arguments here and have MemberLookup return only the methods that
// match the argument count/type, unlike we are doing now (we delay this
// decision).
//
// This is so we can catch correctly attempts to invoke instance methods
// from a static body (scan for error 120 in ResolveSimpleName).
//
//
// FIXME: Potential optimization, have a static ArrayList
//
public static Expression MemberLookup (CompilerContext ctx, TypeSpec container_type, TypeSpec queried_type, string name, int arity,
MemberKind mt, BindingRestriction bf, Location loc)
{
return MemberLookup (ctx, container_type, null, queried_type, name, arity, mt, bf, loc);
}
//
// Lookup type `queried_type' for code in class `container_type' with a qualifier of
// `qualifier_type' or null to lookup members in the current class.
//
public static Expression MemberLookup (CompilerContext ctx, TypeSpec container_type,
TypeSpec qualifier_type, TypeSpec queried_type,
string name, int arity, MemberKind mt,
BindingRestriction binding, Location loc)
{
var mi = TypeManager.MemberLookup (container_type, qualifier_type,
queried_type, mt, binding, name, arity, null);
if (mi == null)
return null;
var first = mi [0];
if (mi.Count > 1) {
foreach (var mc in mi) {
if (mc is MethodSpec)
return new MethodGroupExpr (mi, queried_type, loc);
}
ctx.Report.SymbolRelatedToPreviousError (mi [1]);
ctx.Report.SymbolRelatedToPreviousError (first);
ctx.Report.Error (229, loc, "Ambiguity between `{0}' and `{1}'",
first.GetSignatureForError (), mi [1].GetSignatureForError ());
}
if (first is MethodSpec)
return new MethodGroupExpr (mi, queried_type, loc);
return ExprClassFromMemberInfo (container_type, first, loc);
}
public static Expression MemberLookup (CompilerContext ctx, TypeSpec container_type, TypeSpec queried_type,
string name, int arity, BindingRestriction binding, Location loc)
{
return MemberLookup (ctx, container_type, null, queried_type, name, arity,
MemberKind.All, binding | BindingRestriction.AccessibleOnly, loc);
}
public static Expression MemberLookup (CompilerContext ctx, TypeSpec container_type, TypeSpec qualifier_type,
TypeSpec queried_type, string name, int arity, BindingRestriction binding, Location loc)
{
return MemberLookup (ctx, container_type, qualifier_type, queried_type,
name, arity, MemberKind.All, binding | BindingRestriction.AccessibleOnly, loc);
}
///
/// This is a wrapper for MemberLookup that is not used to "probe", but
/// to find a final definition. If the final definition is not found, we
/// look for private members and display a useful debugging message if we
/// find it.
///
protected Expression MemberLookupFinal (ResolveContext ec, TypeSpec qualifier_type,
TypeSpec queried_type, string name, int arity,
MemberKind mt, BindingRestriction bf,
Location loc)
{
Expression e;
int errors = ec.Report.Errors;
e = MemberLookup (ec.Compiler, ec.CurrentType, qualifier_type, queried_type, name, arity, mt, bf, loc);
if (e != null || errors != ec.Report.Errors)
return e;
// No errors were reported by MemberLookup, but there was an error.
return Error_MemberLookupFailed (ec, ec.CurrentType, qualifier_type, queried_type,
name, arity, null, mt, bf);
}
protected virtual Expression Error_MemberLookupFailed (ResolveContext ec, TypeSpec container_type, TypeSpec qualifier_type,
TypeSpec queried_type, string name, int arity, string class_name,
MemberKind mt, BindingRestriction bf)
{
IList lookup = null;
if (queried_type == null) {
class_name = "global::";
} else {
BindingRestriction restriction = bf & BindingRestriction.DeclaredOnly;
lookup = TypeManager.MemberLookup (queried_type, null, queried_type,
mt, restriction, name, arity, null);
if (lookup != null) {
Expression e = Error_MemberLookupFailed (ec, queried_type, lookup);
//
// FIXME: This is still very wrong, it should be done inside
// OverloadResolve to do correct arguments matching.
// Requires MemberLookup accessiblity check removal
//
if (e == null || (mt & (MemberKind.Method | MemberKind.Constructor)) == 0) {
var mi = lookup.First ();
ec.Report.SymbolRelatedToPreviousError (mi);
if ((mi.Modifiers & Modifiers.PROTECTED) != 0 && qualifier_type != null && container_type != null && qualifier_type != container_type &&
TypeManager.IsNestedFamilyAccessible (container_type, mi.DeclaringType)) {
// Although a derived class can access protected members of
// its base class it cannot do so through an instance of the
// base class (CS1540). If the qualifier_type is a base of the
// ec.CurrentType and the lookup succeeds with the latter one,
// then we are in this situation.
Error_CannotAccessProtected (ec, loc, mi, qualifier_type, container_type);
} else {
ErrorIsInaccesible (loc, TypeManager.GetFullNameSignature (mi), ec.Report);
}
}
return e;
}
lookup = TypeManager.MemberLookup (queried_type, null, queried_type,
MemberKind.All, BindingRestriction.None, name, -System.Math.Max (1, arity), null);
}
if (lookup == null) {
if (class_name != null) {
ec.Report.Error (103, loc, "The name `{0}' does not exist in the current context",
name);
} else {
Error_TypeDoesNotContainDefinition (ec, queried_type, name);
}
return null;
}
var mge = Error_MemberLookupFailed (ec, queried_type, lookup);
if (arity > 0 && mge != null) {
mge.SetTypeArguments (ec, new TypeArguments (new FullNamedExpression [arity]));
}
return mge.Resolve (ec);
}
protected virtual MemberExpr Error_MemberLookupFailed (ResolveContext ec, TypeSpec type, IList members)
{
if (members.Any ((m) => !(m is MethodSpec)))
return (MemberExpr) ExprClassFromMemberInfo (type, members.First (), loc);
// By default propagate the closest candidates upwards
return new MethodGroupExpr (members, type, loc, true);
}
protected virtual void Error_NegativeArrayIndex (ResolveContext ec, Location loc)
{
throw new NotImplementedException ();
}
protected void Error_PointerInsideExpressionTree (ResolveContext ec)
{
ec.Report.Error (1944, loc, "An expression tree cannot contain an unsafe pointer operation");
}
///
/// Returns an expression that can be used to invoke operator true
/// on the expression if it exists.
///
protected static Expression GetOperatorTrue (ResolveContext ec, Expression e, Location loc)
{
return GetOperatorTrueOrFalse (ec, e, true, loc);
}
///
/// Returns an expression that can be used to invoke operator false
/// on the expression if it exists.
///
static public Expression GetOperatorFalse (ResolveContext ec, Expression e, Location loc)
{
return GetOperatorTrueOrFalse (ec, e, false, loc);
}
static Expression GetOperatorTrueOrFalse (ResolveContext ec, Expression e, bool is_true, Location loc)
{
var op = is_true ? Operator.OpType.True : Operator.OpType.False;
var methods = MemberCache.GetUserOperator (e.type, op, false);
if (methods == null)
return null;
var mg = new MethodGroupExpr (methods, e.type, loc);
Arguments arguments = new Arguments (1);
arguments.Add (new Argument (e));
mg = mg.OverloadResolve (ec, ref arguments, false, loc);
if (mg == null)
return null;
return new UserOperatorCall (mg.BestCandidate, arguments, null, loc);
}
public virtual string ExprClassName
{
get {
switch (eclass){
case ExprClass.Unresolved:
return "Unresolved";
case ExprClass.Value:
return "value";
case ExprClass.Variable:
return "variable";
case ExprClass.Namespace:
return "namespace";
case ExprClass.Type:
return "type";
case ExprClass.MethodGroup:
return "method group";
case ExprClass.PropertyAccess:
return "property access";
case ExprClass.EventAccess:
return "event access";
case ExprClass.IndexerAccess:
return "indexer access";
case ExprClass.Nothing:
return "null";
case ExprClass.TypeParameter:
return "type parameter";
}
throw new Exception ("Should not happen");
}
}
///
/// Reports that we were expecting `expr' to be of class `expected'
///
public void Error_UnexpectedKind (Report r, MemberCore mc, string expected, Location loc)
{
Error_UnexpectedKind (r, mc, expected, ExprClassName, loc);
}
public void Error_UnexpectedKind (Report r, MemberCore mc, string expected, string was, Location loc)
{
string name;
if (mc != null)
name = mc.GetSignatureForError ();
else
name = GetSignatureForError ();
r.Error (118, loc, "`{0}' is a `{1}' but a `{2}' was expected",
name, was, expected);
}
public void Error_UnexpectedKind (ResolveContext ec, ResolveFlags flags, Location loc)
{
string [] valid = new string [4];
int count = 0;
if ((flags & ResolveFlags.VariableOrValue) != 0) {
valid [count++] = "variable";
valid [count++] = "value";
}
if ((flags & ResolveFlags.Type) != 0)
valid [count++] = "type";
if ((flags & ResolveFlags.MethodGroup) != 0)
valid [count++] = "method group";
if (count == 0)
valid [count++] = "unknown";
StringBuilder sb = new StringBuilder (valid [0]);
for (int i = 1; i < count - 1; i++) {
sb.Append ("', `");
sb.Append (valid [i]);
}
if (count > 1) {
sb.Append ("' or `");
sb.Append (valid [count - 1]);
}
ec.Report.Error (119, loc,
"Expression denotes a `{0}', where a `{1}' was expected", ExprClassName, sb.ToString ());
}
public static void UnsafeError (ResolveContext ec, Location loc)
{
UnsafeError (ec.Report, loc);
}
public static void UnsafeError (Report Report, Location loc)
{
Report.Error (214, loc, "Pointers and fixed size buffers may only be used in an unsafe context");
}
//
// Returns the size of type `t' if known, otherwise, 0
//
public static int GetTypeSize (TypeSpec t)
{
if (t == TypeManager.int32_type ||
t == TypeManager.uint32_type ||
t == TypeManager.float_type)
return 4;
else if (t == TypeManager.int64_type ||
t == TypeManager.uint64_type ||
t == TypeManager.double_type)
return 8;
else if (t == TypeManager.byte_type ||
t == TypeManager.sbyte_type ||
t == TypeManager.bool_type)
return 1;
else if (t == TypeManager.short_type ||
t == TypeManager.char_type ||
t == TypeManager.ushort_type)
return 2;
else if (t == TypeManager.decimal_type)
return 16;
else
return 0;
}
protected void Error_CannotCallAbstractBase (ResolveContext ec, string name)
{
ec.Report.Error (205, loc, "Cannot call an abstract base member `{0}'", name);
}
protected void Error_CannotModifyIntermediateExpressionValue (ResolveContext ec)
{
ec.Report.SymbolRelatedToPreviousError (type);
if (ec.CurrentInitializerVariable != null) {
ec.Report.Error (1918, loc, "Members of value type `{0}' cannot be assigned using a property `{1}' object initializer",
TypeManager.CSharpName (type), GetSignatureForError ());
} else {
ec.Report.Error (1612, loc, "Cannot modify a value type return value of `{0}'. Consider storing the value in a temporary variable",
GetSignatureForError ());
}
}
//
// Converts `source' to an int, uint, long or ulong.
//
protected Expression ConvertExpressionToArrayIndex (ResolveContext ec, Expression source)
{
if (source.type == InternalType.Dynamic) {
Arguments args = new Arguments (1);
args.Add (new Argument (source));
return new DynamicConversion (TypeManager.int32_type, CSharpBinderFlags.ConvertArrayIndex, args, loc).Resolve (ec);
}
Expression converted;
using (ec.Set (ResolveContext.Options.CheckedScope)) {
converted = Convert.ImplicitConversion (ec, source, TypeManager.int32_type, source.loc);
if (converted == null)
converted = Convert.ImplicitConversion (ec, source, TypeManager.uint32_type, source.loc);
if (converted == null)
converted = Convert.ImplicitConversion (ec, source, TypeManager.int64_type, source.loc);
if (converted == null)
converted = Convert.ImplicitConversion (ec, source, TypeManager.uint64_type, source.loc);
if (converted == null) {
source.Error_ValueCannotBeConverted (ec, source.loc, TypeManager.int32_type, false);
return null;
}
}
//
// Only positive constants are allowed at compile time
//
Constant c = converted as Constant;
if (c != null && c.IsNegative)
Error_NegativeArrayIndex (ec, source.loc);
// No conversion needed to array index
if (converted.Type == TypeManager.int32_type)
return converted;
return new ArrayIndexCast (converted).Resolve (ec);
}
//
// Derived classes implement this method by cloning the fields that
// could become altered during the Resolve stage
//
// Only expressions that are created for the parser need to implement
// this.
//
protected virtual void CloneTo (CloneContext clonectx, Expression target)
{
throw new NotImplementedException (
String.Format (
"CloneTo not implemented for expression {0}", this.GetType ()));
}
//
// Clones an expression created by the parser.
//
// We only support expressions created by the parser so far, not
// expressions that have been resolved (many more classes would need
// to implement CloneTo).
//
// This infrastructure is here merely for Lambda expressions which
// compile the same code using different type values for the same
// arguments to find the correct overload
//
public Expression Clone (CloneContext clonectx)
{
Expression cloned = (Expression) MemberwiseClone ();
CloneTo (clonectx, cloned);
return cloned;
}
//
// Implementation of expression to expression tree conversion
//
public abstract Expression CreateExpressionTree (ResolveContext ec);
protected Expression CreateExpressionFactoryCall (ResolveContext ec, string name, Arguments args)
{
return CreateExpressionFactoryCall (ec, name, null, args, loc);
}
protected Expression CreateExpressionFactoryCall (ResolveContext ec, string name, TypeArguments typeArguments, Arguments args)
{
return CreateExpressionFactoryCall (ec, name, typeArguments, args, loc);
}
public static Expression CreateExpressionFactoryCall (ResolveContext ec, string name, TypeArguments typeArguments, Arguments args, Location loc)
{
return new Invocation (new MemberAccess (CreateExpressionTypeExpression (ec, loc), name, typeArguments, loc), args);
}
protected static TypeExpr CreateExpressionTypeExpression (ResolveContext ec, Location loc)
{
TypeExpr texpr = TypeManager.expression_type_expr;
if (texpr == null) {
TypeSpec t = TypeManager.CoreLookupType (ec.Compiler, "System.Linq.Expressions", "Expression", MemberKind.Class, true);
if (t == null)
return null;
TypeManager.expression_type_expr = texpr = new TypeExpression (t, Location.Null);
}
return texpr;
}
//
// Implemented by all expressions which support conversion from
// compiler expression to invokable runtime expression. Used by
// dynamic C# binder.
//
public virtual SLE.Expression MakeExpression (BuilderContext ctx)
{
throw new NotImplementedException ("MakeExpression for " + GetType ());
}
}
///
/// This is just a base class for expressions that can
/// appear on statements (invocations, object creation,
/// assignments, post/pre increment and decrement). The idea
/// being that they would support an extra Emition interface that
/// does not leave a result on the stack.
///
public abstract class ExpressionStatement : Expression {
public ExpressionStatement ResolveStatement (BlockContext ec)
{
Expression e = Resolve (ec);
if (e == null)
return null;
ExpressionStatement es = e as ExpressionStatement;
if (es == null)
Error_InvalidExpressionStatement (ec);
return es;
}
///
/// Requests the expression to be emitted in a `statement'
/// context. This means that no new value is left on the
/// stack after invoking this method (constrasted with
/// Emit that will always leave a value on the stack).
///
public abstract void EmitStatement (EmitContext ec);
public override void EmitSideEffect (EmitContext ec)
{
EmitStatement (ec);
}
}
///
/// This kind of cast is used to encapsulate the child
/// whose type is child.Type into an expression that is
/// reported to return "return_type". This is used to encapsulate
/// expressions which have compatible types, but need to be dealt
/// at higher levels with.
///
/// For example, a "byte" expression could be encapsulated in one
/// of these as an "unsigned int". The type for the expression
/// would be "unsigned int".
///
///
public abstract class TypeCast : Expression
{
protected readonly Expression child;
protected TypeCast (Expression child, TypeSpec return_type)
{
eclass = child.eclass;
loc = child.Location;
type = return_type;
this.child = child;
}
public Expression Child {
get {
return child;
}
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
Arguments args = new Arguments (2);
args.Add (new Argument (child.CreateExpressionTree (ec)));
args.Add (new Argument (new TypeOf (new TypeExpression (type, loc), loc)));
if (type.IsPointer || child.Type.IsPointer)
Error_PointerInsideExpressionTree (ec);
return CreateExpressionFactoryCall (ec, ec.HasSet (ResolveContext.Options.CheckedScope) ? "ConvertChecked" : "Convert", args);
}
protected override Expression DoResolve (ResolveContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override void Emit (EmitContext ec)
{
child.Emit (ec);
}
public override SLE.Expression MakeExpression (BuilderContext ctx)
{
return ctx.HasSet (BuilderContext.Options.CheckedScope) ?
SLE.Expression.ConvertChecked (child.MakeExpression (ctx), type.GetMetaInfo ()) :
SLE.Expression.Convert (child.MakeExpression (ctx), type.GetMetaInfo ());
}
protected override void CloneTo (CloneContext clonectx, Expression t)
{
// Nothing to clone
}
public override bool IsNull {
get { return child.IsNull; }
}
}
public class EmptyCast : TypeCast {
EmptyCast (Expression child, TypeSpec target_type)
: base (child, target_type)
{
}
public static Expression Create (Expression child, TypeSpec type)
{
Constant c = child as Constant;
if (c != null)
return new EmptyConstantCast (c, type);
EmptyCast e = child as EmptyCast;
if (e != null)
return new EmptyCast (e.child, type);
return new EmptyCast (child, type);
}
public override void EmitBranchable (EmitContext ec, Label label, bool on_true)
{
child.EmitBranchable (ec, label, on_true);
}
public override void EmitSideEffect (EmitContext ec)
{
child.EmitSideEffect (ec);
}
}
//
// Used for predefined class library user casts (no obsolete check, etc.)
//
public class OperatorCast : TypeCast {
MethodSpec conversion_operator;
public OperatorCast (Expression child, TypeSpec target_type)
: this (child, target_type, false)
{
}
public OperatorCast (Expression child, TypeSpec target_type, bool find_explicit)
: base (child, target_type)
{
conversion_operator = GetConversionOperator (find_explicit);
if (conversion_operator == null)
throw new InternalErrorException ("Outer conversion routine is out of sync");
}
// Returns the implicit operator that converts from
// 'child.Type' to our target type (type)
MethodSpec GetConversionOperator (bool find_explicit)
{
var op = find_explicit ? Operator.OpType.Explicit : Operator.OpType.Implicit;
var mi = MemberCache.GetUserOperator (child.Type, op, true);
if (mi == null){
mi = MemberCache.GetUserOperator (type, op, true);
}
foreach (MethodSpec oper in mi) {
if (oper.ReturnType != type)
continue;
if (oper.Parameters.Types [0] == child.Type)
return oper;
}
return null;
}
public override void Emit (EmitContext ec)
{
child.Emit (ec);
ec.Emit (OpCodes.Call, conversion_operator);
}
}
///
/// This is a numeric cast to a Decimal
///
public class CastToDecimal : OperatorCast {
public CastToDecimal (Expression child)
: this (child, false)
{
}
public CastToDecimal (Expression child, bool find_explicit)
: base (child, TypeManager.decimal_type, find_explicit)
{
}
}
///
/// This is an explicit numeric cast from a Decimal
///
public class CastFromDecimal : TypeCast
{
static Dictionary operators;
public CastFromDecimal (Expression child, TypeSpec return_type)
: base (child, return_type)
{
if (child.Type != TypeManager.decimal_type)
throw new ArgumentException ("Expected decimal child " + child.Type.GetSignatureForError ());
}
// Returns the explicit operator that converts from an
// express of type System.Decimal to 'type'.
public Expression Resolve ()
{
if (operators == null) {
var all_oper = MemberCache.GetUserOperator (TypeManager.decimal_type, Operator.OpType.Explicit, true);
operators = new Dictionary ();
foreach (MethodSpec oper in all_oper) {
AParametersCollection pd = oper.Parameters;
if (pd.Types [0] == TypeManager.decimal_type)
operators.Add (oper.ReturnType, oper);
}
}
return operators.ContainsKey (type) ? this : null;
}
public override void Emit (EmitContext ec)
{
child.Emit (ec);
ec.Emit (OpCodes.Call, operators [type]);
}
public static void Reset ()
{
operators = null;
}
}
//
// Constant specialization of EmptyCast.
// We need to special case this since an empty cast of
// a constant is still a constant.
//
public class EmptyConstantCast : Constant
{
public Constant child;
public EmptyConstantCast (Constant child, TypeSpec type)
: base (child.Location)
{
if (child == null)
throw new ArgumentNullException ("child");
this.child = child;
this.eclass = child.eclass;
this.type = type;
}
public override string AsString ()
{
return child.AsString ();
}
public override object GetValue ()
{
return child.GetValue ();
}
public override Constant ConvertExplicitly (bool in_checked_context, TypeSpec target_type)
{
if (child.Type == target_type)
return child;
// FIXME: check that 'type' can be converted to 'target_type' first
return child.ConvertExplicitly (in_checked_context, target_type);
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
Arguments args = Arguments.CreateForExpressionTree (ec, null,
child.CreateExpressionTree (ec),
new TypeOf (new TypeExpression (type, loc), loc));
if (type.IsPointer)
Error_PointerInsideExpressionTree (ec);
return CreateExpressionFactoryCall (ec, "Convert", args);
}
public override bool IsDefaultValue {
get { return child.IsDefaultValue; }
}
public override bool IsNegative {
get { return child.IsNegative; }
}
public override bool IsNull {
get { return child.IsNull; }
}
public override bool IsOneInteger {
get { return child.IsOneInteger; }
}
public override bool IsZeroInteger {
get { return child.IsZeroInteger; }
}
protected override Expression DoResolve (ResolveContext rc)
{
return this;
}
public override void Emit (EmitContext ec)
{
child.Emit (ec);
}
public override void EmitBranchable (EmitContext ec, Label label, bool on_true)
{
child.EmitBranchable (ec, label, on_true);
// Only to make verifier happy
if (TypeManager.IsGenericParameter (type) && child.IsNull)
ec.Emit (OpCodes.Unbox_Any, type);
}
public override void EmitSideEffect (EmitContext ec)
{
child.EmitSideEffect (ec);
}
public override Constant ConvertImplicitly (ResolveContext rc, TypeSpec target_type)
{
// FIXME: Do we need to check user conversions?
if (!Convert.ImplicitStandardConversionExists (this, target_type))
return null;
return child.ConvertImplicitly (rc, target_type);
}
}
///
/// This class is used to wrap literals which belong inside Enums
///
public class EnumConstant : Constant
{
public Constant Child;
public EnumConstant (Constant child, TypeSpec enum_type)
: base (child.Location)
{
this.Child = child;
this.type = enum_type;
}
protected EnumConstant (Location loc)
: base (loc)
{
}
protected override Expression DoResolve (ResolveContext rc)
{
Child = Child.Resolve (rc);
this.eclass = ExprClass.Value;
return this;
}
public override void Emit (EmitContext ec)
{
Child.Emit (ec);
}
public override void EncodeAttributeValue (IMemberContext rc, AttributeEncoder enc, TypeSpec targetType)
{
Child.EncodeAttributeValue (rc, enc, Child.Type);
}
public override void EmitBranchable (EmitContext ec, Label label, bool on_true)
{
Child.EmitBranchable (ec, label, on_true);
}
public override void EmitSideEffect (EmitContext ec)
{
Child.EmitSideEffect (ec);
}
public override string GetSignatureForError()
{
return TypeManager.CSharpName (Type);
}
public override object GetValue ()
{
return Child.GetValue ();
}
public override object GetTypedValue ()
{
// FIXME: runtime is not ready to work with just emited enums
if (!RootContext.StdLib) {
return Child.GetValue ();
}
#if MS_COMPATIBLE
// Small workaround for big problem
// System.Enum.ToObject cannot be called on dynamic types
// EnumBuilder has to be used, but we cannot use EnumBuilder
// because it does not properly support generics
//
// This works only sometimes
//
if (type.MemberDefinition is TypeContainer)
return Child.GetValue ();
#endif
return System.Enum.ToObject (type.GetMetaInfo (), Child.GetValue ());
}
public override string AsString ()
{
return Child.AsString ();
}
public EnumConstant Increment()
{
return new EnumConstant (((IntegralConstant) Child).Increment (), type);
}
public override bool IsDefaultValue {
get {
return Child.IsDefaultValue;
}
}
public override bool IsZeroInteger {
get { return Child.IsZeroInteger; }
}
public override bool IsNegative {
get {
return Child.IsNegative;
}
}
public override Constant ConvertExplicitly(bool in_checked_context, TypeSpec target_type)
{
if (Child.Type == target_type)
return Child;
return Child.ConvertExplicitly (in_checked_context, target_type);
}
public override Constant ConvertImplicitly (ResolveContext rc, TypeSpec type)
{
if (this.type == type) {
return this;
}
if (!Convert.ImplicitStandardConversionExists (this, type)){
return null;
}
return Child.ConvertImplicitly (rc, type);
}
}
///
/// This kind of cast is used to encapsulate Value Types in objects.
///
/// The effect of it is to box the value type emitted by the previous
/// operation.
///
public class BoxedCast : TypeCast {
public BoxedCast (Expression expr, TypeSpec target_type)
: base (expr, target_type)
{
eclass = ExprClass.Value;
}
protected override Expression DoResolve (ResolveContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override void EncodeAttributeValue (IMemberContext rc, AttributeEncoder enc, TypeSpec targetType)
{
enc.Encode (child.Type);
child.EncodeAttributeValue (rc, enc, child.Type);
}
public override void Emit (EmitContext ec)
{
base.Emit (ec);
ec.Emit (OpCodes.Box, child.Type);
}
public override void EmitSideEffect (EmitContext ec)
{
// boxing is side-effectful, since it involves runtime checks, except when boxing to Object or ValueType
// so, we need to emit the box+pop instructions in most cases
if (TypeManager.IsStruct (child.Type) &&
(type == TypeManager.object_type || type == TypeManager.value_type))
child.EmitSideEffect (ec);
else
base.EmitSideEffect (ec);
}
}
public class UnboxCast : TypeCast {
public UnboxCast (Expression expr, TypeSpec return_type)
: base (expr, return_type)
{
}
protected override Expression DoResolve (ResolveContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
if (right_side == EmptyExpression.LValueMemberAccess || right_side == EmptyExpression.LValueMemberOutAccess)
ec.Report.Error (445, loc, "Cannot modify the result of an unboxing conversion");
return base.DoResolveLValue (ec, right_side);
}
public override void Emit (EmitContext ec)
{
base.Emit (ec);
ec.Emit (OpCodes.Unbox_Any, type);
}
}
///
/// This is used to perform explicit numeric conversions.
///
/// Explicit numeric conversions might trigger exceptions in a checked
/// context, so they should generate the conv.ovf opcodes instead of
/// conv opcodes.
///
public class ConvCast : TypeCast {
public enum Mode : byte {
I1_U1, I1_U2, I1_U4, I1_U8, I1_CH,
U1_I1, U1_CH,
I2_I1, I2_U1, I2_U2, I2_U4, I2_U8, I2_CH,
U2_I1, U2_U1, U2_I2, U2_CH,
I4_I1, I4_U1, I4_I2, I4_U2, I4_U4, I4_U8, I4_CH,
U4_I1, U4_U1, U4_I2, U4_U2, U4_I4, U4_CH,
I8_I1, I8_U1, I8_I2, I8_U2, I8_I4, I8_U4, I8_U8, I8_CH, I8_I,
U8_I1, U8_U1, U8_I2, U8_U2, U8_I4, U8_U4, U8_I8, U8_CH, U8_I,
CH_I1, CH_U1, CH_I2,
R4_I1, R4_U1, R4_I2, R4_U2, R4_I4, R4_U4, R4_I8, R4_U8, R4_CH,
R8_I1, R8_U1, R8_I2, R8_U2, R8_I4, R8_U4, R8_I8, R8_U8, R8_CH, R8_R4,
I_I8,
}
Mode mode;
public ConvCast (Expression child, TypeSpec return_type, Mode m)
: base (child, return_type)
{
mode = m;
}
protected override Expression DoResolve (ResolveContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override string ToString ()
{
return String.Format ("ConvCast ({0}, {1})", mode, child);
}
public override void Emit (EmitContext ec)
{
base.Emit (ec);
if (ec.HasSet (EmitContext.Options.CheckedScope)) {
switch (mode){
case Mode.I1_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.I1_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.I1_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.I1_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.I1_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.U1_I1: ec.Emit (OpCodes.Conv_Ovf_I1_Un); break;
case Mode.U1_CH: /* nothing */ break;
case Mode.I2_I1: ec.Emit (OpCodes.Conv_Ovf_I1); break;
case Mode.I2_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.I2_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.I2_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.I2_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.I2_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.U2_I1: ec.Emit (OpCodes.Conv_Ovf_I1_Un); break;
case Mode.U2_U1: ec.Emit (OpCodes.Conv_Ovf_U1_Un); break;
case Mode.U2_I2: ec.Emit (OpCodes.Conv_Ovf_I2_Un); break;
case Mode.U2_CH: /* nothing */ break;
case Mode.I4_I1: ec.Emit (OpCodes.Conv_Ovf_I1); break;
case Mode.I4_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.I4_I2: ec.Emit (OpCodes.Conv_Ovf_I2); break;
case Mode.I4_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.I4_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.I4_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.I4_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.U4_I1: ec.Emit (OpCodes.Conv_Ovf_I1_Un); break;
case Mode.U4_U1: ec.Emit (OpCodes.Conv_Ovf_U1_Un); break;
case Mode.U4_I2: ec.Emit (OpCodes.Conv_Ovf_I2_Un); break;
case Mode.U4_U2: ec.Emit (OpCodes.Conv_Ovf_U2_Un); break;
case Mode.U4_I4: ec.Emit (OpCodes.Conv_Ovf_I4_Un); break;
case Mode.U4_CH: ec.Emit (OpCodes.Conv_Ovf_U2_Un); break;
case Mode.I8_I1: ec.Emit (OpCodes.Conv_Ovf_I1); break;
case Mode.I8_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.I8_I2: ec.Emit (OpCodes.Conv_Ovf_I2); break;
case Mode.I8_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.I8_I4: ec.Emit (OpCodes.Conv_Ovf_I4); break;
case Mode.I8_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.I8_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.I8_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.I8_I: ec.Emit (OpCodes.Conv_Ovf_U); break;
case Mode.U8_I1: ec.Emit (OpCodes.Conv_Ovf_I1_Un); break;
case Mode.U8_U1: ec.Emit (OpCodes.Conv_Ovf_U1_Un); break;
case Mode.U8_I2: ec.Emit (OpCodes.Conv_Ovf_I2_Un); break;
case Mode.U8_U2: ec.Emit (OpCodes.Conv_Ovf_U2_Un); break;
case Mode.U8_I4: ec.Emit (OpCodes.Conv_Ovf_I4_Un); break;
case Mode.U8_U4: ec.Emit (OpCodes.Conv_Ovf_U4_Un); break;
case Mode.U8_I8: ec.Emit (OpCodes.Conv_Ovf_I8_Un); break;
case Mode.U8_CH: ec.Emit (OpCodes.Conv_Ovf_U2_Un); break;
case Mode.U8_I: ec.Emit (OpCodes.Conv_Ovf_U_Un); break;
case Mode.CH_I1: ec.Emit (OpCodes.Conv_Ovf_I1_Un); break;
case Mode.CH_U1: ec.Emit (OpCodes.Conv_Ovf_U1_Un); break;
case Mode.CH_I2: ec.Emit (OpCodes.Conv_Ovf_I2_Un); break;
case Mode.R4_I1: ec.Emit (OpCodes.Conv_Ovf_I1); break;
case Mode.R4_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.R4_I2: ec.Emit (OpCodes.Conv_Ovf_I2); break;
case Mode.R4_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.R4_I4: ec.Emit (OpCodes.Conv_Ovf_I4); break;
case Mode.R4_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.R4_I8: ec.Emit (OpCodes.Conv_Ovf_I8); break;
case Mode.R4_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.R4_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.R8_I1: ec.Emit (OpCodes.Conv_Ovf_I1); break;
case Mode.R8_U1: ec.Emit (OpCodes.Conv_Ovf_U1); break;
case Mode.R8_I2: ec.Emit (OpCodes.Conv_Ovf_I2); break;
case Mode.R8_U2: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.R8_I4: ec.Emit (OpCodes.Conv_Ovf_I4); break;
case Mode.R8_U4: ec.Emit (OpCodes.Conv_Ovf_U4); break;
case Mode.R8_I8: ec.Emit (OpCodes.Conv_Ovf_I8); break;
case Mode.R8_U8: ec.Emit (OpCodes.Conv_Ovf_U8); break;
case Mode.R8_CH: ec.Emit (OpCodes.Conv_Ovf_U2); break;
case Mode.R8_R4: ec.Emit (OpCodes.Conv_R4); break;
case Mode.I_I8: ec.Emit (OpCodes.Conv_Ovf_I8_Un); break;
}
} else {
switch (mode){
case Mode.I1_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.I1_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I1_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.I1_U8: ec.Emit (OpCodes.Conv_I8); break;
case Mode.I1_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U1_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.U1_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I2_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.I2_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.I2_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I2_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.I2_U8: ec.Emit (OpCodes.Conv_I8); break;
case Mode.I2_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U2_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.U2_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.U2_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.U2_CH: /* nothing */ break;
case Mode.I4_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.I4_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.I4_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.I4_U4: /* nothing */ break;
case Mode.I4_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I4_U8: ec.Emit (OpCodes.Conv_I8); break;
case Mode.I4_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U4_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.U4_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.U4_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.U4_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U4_I4: /* nothing */ break;
case Mode.U4_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I8_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.I8_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.I8_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.I8_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I8_I4: ec.Emit (OpCodes.Conv_I4); break;
case Mode.I8_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.I8_U8: /* nothing */ break;
case Mode.I8_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.I8_I: ec.Emit (OpCodes.Conv_U); break;
case Mode.U8_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.U8_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.U8_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.U8_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U8_I4: ec.Emit (OpCodes.Conv_I4); break;
case Mode.U8_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.U8_I8: /* nothing */ break;
case Mode.U8_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.U8_I: ec.Emit (OpCodes.Conv_U); break;
case Mode.CH_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.CH_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.CH_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.R4_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.R4_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.R4_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.R4_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.R4_I4: ec.Emit (OpCodes.Conv_I4); break;
case Mode.R4_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.R4_I8: ec.Emit (OpCodes.Conv_I8); break;
case Mode.R4_U8: ec.Emit (OpCodes.Conv_U8); break;
case Mode.R4_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.R8_I1: ec.Emit (OpCodes.Conv_I1); break;
case Mode.R8_U1: ec.Emit (OpCodes.Conv_U1); break;
case Mode.R8_I2: ec.Emit (OpCodes.Conv_I2); break;
case Mode.R8_U2: ec.Emit (OpCodes.Conv_U2); break;
case Mode.R8_I4: ec.Emit (OpCodes.Conv_I4); break;
case Mode.R8_U4: ec.Emit (OpCodes.Conv_U4); break;
case Mode.R8_I8: ec.Emit (OpCodes.Conv_I8); break;
case Mode.R8_U8: ec.Emit (OpCodes.Conv_U8); break;
case Mode.R8_CH: ec.Emit (OpCodes.Conv_U2); break;
case Mode.R8_R4: ec.Emit (OpCodes.Conv_R4); break;
case Mode.I_I8: ec.Emit (OpCodes.Conv_U8); break;
}
}
}
}
public class OpcodeCast : TypeCast {
readonly OpCode op;
public OpcodeCast (Expression child, TypeSpec return_type, OpCode op)
: base (child, return_type)
{
this.op = op;
}
protected override Expression DoResolve (ResolveContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override void Emit (EmitContext ec)
{
base.Emit (ec);
ec.Emit (op);
}
public TypeSpec UnderlyingType {
get { return child.Type; }
}
}
///
/// This kind of cast is used to encapsulate a child and cast it
/// to the class requested
///
public sealed class ClassCast : TypeCast {
readonly bool forced;
public ClassCast (Expression child, TypeSpec return_type)
: base (child, return_type)
{
}
public ClassCast (Expression child, TypeSpec return_type, bool forced)
: base (child, return_type)
{
this.forced = forced;
}
public override void Emit (EmitContext ec)
{
base.Emit (ec);
bool gen = TypeManager.IsGenericParameter (child.Type);
if (gen)
ec.Emit (OpCodes.Box, child.Type);
if (type.IsGenericParameter) {
ec.Emit (OpCodes.Unbox_Any, type);
return;
}
if (gen && !forced)
return;
ec.Emit (OpCodes.Castclass, type);
}
}
//
// Created during resolving pahse when an expression is wrapped or constantified
// and original expression can be used later (e.g. for expression trees)
//
public class ReducedExpression : Expression
{
sealed class ReducedConstantExpression : EmptyConstantCast
{
readonly Expression orig_expr;
public ReducedConstantExpression (Constant expr, Expression orig_expr)
: base (expr, expr.Type)
{
this.orig_expr = orig_expr;
}
public override Constant ConvertImplicitly (ResolveContext rc, TypeSpec target_type)
{
Constant c = base.ConvertImplicitly (rc, target_type);
if (c != null)
c = new ReducedConstantExpression (c, orig_expr);
return c;
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
return orig_expr.CreateExpressionTree (ec);
}
public override Constant ConvertExplicitly (bool in_checked_context, TypeSpec target_type)
{
Constant c = base.ConvertExplicitly (in_checked_context, target_type);
if (c != null)
c = new ReducedConstantExpression (c, orig_expr);
return c;
}
}
sealed class ReducedExpressionStatement : ExpressionStatement
{
readonly Expression orig_expr;
readonly ExpressionStatement stm;
public ReducedExpressionStatement (ExpressionStatement stm, Expression orig)
{
this.orig_expr = orig;
this.stm = stm;
this.loc = orig.Location;
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
return orig_expr.CreateExpressionTree (ec);
}
protected override Expression DoResolve (ResolveContext ec)
{
eclass = stm.eclass;
type = stm.Type;
return this;
}
public override void Emit (EmitContext ec)
{
stm.Emit (ec);
}
public override void EmitStatement (EmitContext ec)
{
stm.EmitStatement (ec);
}
}
readonly Expression expr, orig_expr;
private ReducedExpression (Expression expr, Expression orig_expr)
{
this.expr = expr;
this.eclass = expr.eclass;
this.type = expr.Type;
this.orig_expr = orig_expr;
this.loc = orig_expr.Location;
}
//
// Creates fully resolved expression switcher
//
public static Constant Create (Constant expr, Expression original_expr)
{
if (expr.eclass == ExprClass.Unresolved)
throw new ArgumentException ("Unresolved expression");
return new ReducedConstantExpression (expr, original_expr);
}
public static ExpressionStatement Create (ExpressionStatement s, Expression orig)
{
return new ReducedExpressionStatement (s, orig);
}
//
// Creates unresolved reduce expression. The original expression has to be
// already resolved
//
public static Expression Create (Expression expr, Expression original_expr)
{
Constant c = expr as Constant;
if (c != null)
return Create (c, original_expr);
ExpressionStatement s = expr as ExpressionStatement;
if (s != null)
return Create (s, original_expr);
if (expr.eclass == ExprClass.Unresolved)
throw new ArgumentException ("Unresolved expression");
return new ReducedExpression (expr, original_expr);
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
return orig_expr.CreateExpressionTree (ec);
}
protected override Expression DoResolve (ResolveContext ec)
{
return this;
}
public override void Emit (EmitContext ec)
{
expr.Emit (ec);
}
public override void EmitBranchable (EmitContext ec, Label target, bool on_true)
{
expr.EmitBranchable (ec, target, on_true);
}
public override SLE.Expression MakeExpression (BuilderContext ctx)
{
return orig_expr.MakeExpression (ctx);
}
}
//
// Standard composite pattern
//
public abstract class CompositeExpression : Expression
{
Expression expr;
protected CompositeExpression (Expression expr)
{
this.expr = expr;
this.loc = expr.Location;
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
return expr.CreateExpressionTree (ec);
}
public Expression Child {
get { return expr; }
}
protected override Expression DoResolve (ResolveContext ec)
{
expr = expr.Resolve (ec);
if (expr != null) {
type = expr.Type;
eclass = expr.eclass;
}
return this;
}
public override void Emit (EmitContext ec)
{
expr.Emit (ec);
}
public override bool IsNull {
get { return expr.IsNull; }
}
}
//
// Base of expressions used only to narrow resolve flow
//
public abstract class ShimExpression : Expression
{
protected Expression expr;
protected ShimExpression (Expression expr)
{
this.expr = expr;
}
protected override void CloneTo (CloneContext clonectx, Expression t)
{
if (expr == null)
return;
ShimExpression target = (ShimExpression) t;
target.expr = expr.Clone (clonectx);
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
throw new NotSupportedException ("ET");
}
public override void Emit (EmitContext ec)
{
throw new InternalErrorException ("Missing Resolve call");
}
public Expression Expr {
get { return expr; }
}
}
//
// Unresolved type name expressions
//
public abstract class ATypeNameExpression : FullNamedExpression
{
string name;
protected TypeArguments targs;
protected ATypeNameExpression (string name, Location l)
{
this.name = name;
loc = l;
}
protected ATypeNameExpression (string name, TypeArguments targs, Location l)
{
this.name = name;
this.targs = targs;
loc = l;
}
protected ATypeNameExpression (string name, int arity, Location l)
: this (name, new UnboundTypeArguments (arity), l)
{
}
#region Properties
protected int Arity {
get {
return targs == null ? 0 : targs.Count;
}
}
public bool HasTypeArguments {
get {
return targs != null && !targs.IsEmpty;
}
}
public string Name {
get {
return name;
}
set {
name = value;
}
}
public TypeArguments TypeArguments {
get {
return targs;
}
}
#endregion
public override bool Equals (object obj)
{
ATypeNameExpression atne = obj as ATypeNameExpression;
return atne != null && atne.Name == Name &&
(targs == null || targs.Equals (atne.targs));
}
public override int GetHashCode ()
{
return Name.GetHashCode ();
}
// TODO: Move it to MemberCore
public static string GetMemberType (MemberCore mc)
{
if (mc is Property)
return "property";
if (mc is Indexer)
return "indexer";
if (mc is FieldBase)
return "field";
if (mc is MethodCore)
return "method";
if (mc is EnumMember)
return "enum";
if (mc is Event)
return "event";
return "type";
}
public override string GetSignatureForError ()
{
if (targs != null) {
return Name + "<" + targs.GetSignatureForError () + ">";
}
return Name;
}
}
///
/// SimpleName expressions are formed of a single word and only happen at the beginning
/// of a dotted-name.
///
public class SimpleName : ATypeNameExpression
{
public SimpleName (string name, Location l)
: base (name, l)
{
}
public SimpleName (string name, TypeArguments args, Location l)
: base (name, args, l)
{
}
public SimpleName (string name, int arity, Location l)
: base (name, arity, l)
{
}
public SimpleName GetMethodGroup ()
{
return new SimpleName (Name, targs, loc);
}
protected virtual void Error_TypeOrNamespaceNotFound (IMemberContext ec)
{
if (ec.CurrentType != null) {
if (ec.CurrentMemberDefinition != null) {
MemberCore mc = ec.CurrentMemberDefinition.Parent.GetDefinition (Name);
if (mc != null) {
Error_UnexpectedKind (ec.Compiler.Report, mc, "type", GetMemberType (mc), loc);
return;
}
}
/*
// TODO MemberCache: Implement
string ns = ec.CurrentType.Namespace;
string fullname = (ns.Length > 0) ? ns + "." + Name : Name;
foreach (Assembly a in GlobalRootNamespace.Instance.Assemblies) {
var type = a.GetType (fullname);
if (type != null) {
ec.Compiler.Report.SymbolRelatedToPreviousError (type);
Expression.ErrorIsInaccesible (loc, TypeManager.CSharpName (type), ec.Compiler.Report);
return;
}
}
if (ec.CurrentTypeDefinition != null) {
TypeSpec t = ec.CurrentTypeDefinition.LookupAnyGeneric (Name);
if (t != null) {
Namespace.Error_InvalidNumberOfTypeArguments (ec.Compiler.Report, t, loc);
return;
}
}
*/
}
FullNamedExpression retval = ec.LookupNamespaceOrType (Name, -System.Math.Max (1, Arity), loc, true);
if (retval != null) {
Error_TypeArgumentsCannotBeUsed (ec.Compiler.Report, loc, retval.Type, Arity);
/*
var te = retval as TypeExpr;
if (HasTypeArguments && te != null && !te.Type.IsGeneric)
retval.Error_TypeArgumentsCannotBeUsed (ec.Compiler.Report, loc);
else
Namespace.Error_InvalidNumberOfTypeArguments (ec.Compiler.Report, retval.Type, loc);
*/
return;
}
NamespaceEntry.Error_NamespaceNotFound (loc, Name, ec.Compiler.Report);
}
protected override Expression DoResolve (ResolveContext ec)
{
return SimpleNameResolve (ec, null, false);
}
public override Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
return SimpleNameResolve (ec, right_side, false);
}
public Expression DoResolve (ResolveContext ec, bool intermediate)
{
return SimpleNameResolve (ec, null, intermediate);
}
public override FullNamedExpression ResolveAsTypeStep (IMemberContext ec, bool silent)
{
int errors = ec.Compiler.Report.Errors;
FullNamedExpression fne = ec.LookupNamespaceOrType (Name, Arity, loc, /*ignore_cs0104=*/ false);
if (fne != null) {
if (fne.Type != null && Arity > 0) {
if (HasTypeArguments) {
GenericTypeExpr ct = new GenericTypeExpr (fne.Type, targs, loc);
return ct.ResolveAsTypeStep (ec, false);
}
return new GenericOpenTypeExpr (fne.Type, loc);
}
//
// dynamic namespace is ignored when dynamic is allowed (does not apply to types)
//
if (!(fne is Namespace))
return fne;
}
if (Arity == 0 && Name == "dynamic" && RootContext.Version > LanguageVersion.V_3) {
if (!PredefinedAttributes.Get.Dynamic.IsDefined) {
ec.Compiler.Report.Error (1980, Location,
"Dynamic keyword requires `{0}' to be defined. Are you missing System.Core.dll assembly reference?",
PredefinedAttributes.Get.Dynamic.GetSignatureForError ());
}
return new DynamicTypeExpr (loc);
}
if (fne != null)
return fne;
if (silent || errors != ec.Compiler.Report.Errors)
return null;
Error_TypeOrNamespaceNotFound (ec);
return null;
}
Expression SimpleNameResolve (ResolveContext ec, Expression right_side, bool intermediate)
{
Expression e = DoSimpleNameResolve (ec, right_side, intermediate);
if (e == null)
return null;
if (ec.CurrentBlock == null || ec.CurrentBlock.CheckInvariantMeaningInBlock (Name, e, Location))
return e;
return null;
}
///
/// 7.5.2: Simple Names.
///
/// Local Variables and Parameters are handled at
/// parse time, so they never occur as SimpleNames.
///
/// The `intermediate' flag is used by MemberAccess only
/// and it is used to inform us that it is ok for us to
/// avoid the static check, because MemberAccess might end
/// up resolving the Name as a Type name and the access as
/// a static type access.
///
/// ie: Type Type; .... { Type.GetType (""); }
///
/// Type is both an instance variable and a Type; Type.GetType
/// is the static method not an instance method of type.
///
Expression DoSimpleNameResolve (ResolveContext ec, Expression right_side, bool intermediate)
{
Expression e = null;
//
// Stage 1: Performed by the parser (binding to locals or parameters).
//
Block current_block = ec.CurrentBlock;
if (current_block != null){
LocalInfo vi = current_block.GetLocalInfo (Name);
if (vi != null){
e = new LocalVariableReference (ec.CurrentBlock, Name, loc);
if (right_side != null) {
e = e.ResolveLValue (ec, right_side);
} else {
if (intermediate) {
using (ec.With (ResolveContext.Options.DoFlowAnalysis, false)) {
e = e.Resolve (ec, ResolveFlags.VariableOrValue);
}
} else {
e = e.Resolve (ec, ResolveFlags.VariableOrValue);
}
}
if (e != null && Arity > 0)
e.Error_TypeArgumentsCannotBeUsed (ec.Report, loc, null, 0);
return e;
}
e = current_block.Toplevel.GetParameterReference (Name, loc);
if (e != null) {
if (right_side != null)
e = e.ResolveLValue (ec, right_side);
else
e = e.Resolve (ec);
if (e != null && Arity > 0)
e.Error_TypeArgumentsCannotBeUsed (ec.Report, loc, null, 0);
return e;
}
}
//
// Stage 2: Lookup members
//
int arity = HasTypeArguments ? Arity : -1;
// TypeSpec almost_matched_type = null;
// IList almost_matched = null;
for (TypeSpec lookup_ds = ec.CurrentType; lookup_ds != null; lookup_ds = lookup_ds.DeclaringType) {
e = MemberLookup (ec.Compiler, ec.CurrentType, lookup_ds, Name, arity, BindingRestriction.DefaultMemberLookup, loc);
if (e != null) {
PropertyExpr pe = e as PropertyExpr;
if (pe != null) {
// since TypeManager.MemberLookup doesn't know if we're doing a lvalue access or not,
// it doesn't know which accessor to check permissions against
if (pe.PropertyInfo.Kind == MemberKind.Property && pe.IsAccessibleFrom (ec.CurrentType, right_side != null))
break;
} else if (e is EventExpr) {
if (((EventExpr) e).IsAccessibleFrom (ec.CurrentType))
break;
} else if (HasTypeArguments && e is TypeExpression) {
e = new GenericTypeExpr (e.Type, targs, loc).ResolveAsTypeStep (ec, false);
break;
} else {
break;
}
e = null;
}
/*
if (almost_matched == null && almost_matched_members.Count > 0) {
almost_matched_type = lookup_ds;
almost_matched = new List(almost_matched_members);
}
*/
}
if (e == null) {
/*
if (almost_matched == null && almost_matched_members.Count > 0) {
almost_matched_type = ec.CurrentType;
almost_matched = new List (almost_matched_members);
}
*/
e = ResolveAsTypeStep (ec, true);
}
if (e == null) {
if (current_block != null) {
IKnownVariable ikv = current_block.Explicit.GetKnownVariable (Name);
if (ikv != null) {
LocalInfo li = ikv as LocalInfo;
// Supress CS0219 warning
if (li != null)
li.Used = true;
Error_VariableIsUsedBeforeItIsDeclared (ec.Report, Name);
return null;
}
}
if (RootContext.EvalMode){
var fi = Evaluator.LookupField (Name);
if (fi != null)
return new FieldExpr (fi.Item1, loc).Resolve (ec);
}
/*
if (almost_matched != null)
almost_matched_members = almost_matched;
if (almost_matched_type == null)
almost_matched_type = ec.CurrentType;
*/
string type_name = ec.MemberContext.CurrentType == null ? null : ec.MemberContext.CurrentType.Name;
return Error_MemberLookupFailed (ec, ec.CurrentType, null, ec.CurrentType, Name, arity,
type_name, MemberKind.All, BindingRestriction.AccessibleOnly);
}
if (e is MemberExpr) {
MemberExpr me = (MemberExpr) e;
// TODO: It's used by EventExpr -> FieldExpr transformation only
me = me.ResolveMemberAccess (ec, null, null);
if (HasTypeArguments) {
if (!targs.Resolve (ec))
return null;
me.SetTypeArguments (ec, targs);
}
if (intermediate)
return me;
return (right_side != null)
? me.DoResolveLValue (ec, right_side)
: me.Resolve (ec);
}
return e;
}
}
///
/// Represents a namespace or a type. The name of the class was inspired by
/// section 10.8.1 (Fully Qualified Names).
///
public abstract class FullNamedExpression : Expression
{
protected override void CloneTo (CloneContext clonectx, Expression target)
{
// Do nothing, most unresolved type expressions cannot be
// resolved to different type
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
throw new NotSupportedException ("ET");
}
public override FullNamedExpression ResolveAsTypeStep (IMemberContext ec, bool silent)
{
return this;
}
public override void Emit (EmitContext ec)
{
throw new InternalErrorException ("FullNamedExpression `{0}' found in resolved tree",
GetSignatureForError ());
}
}
///
/// Expression that evaluates to a type
///
public abstract class TypeExpr : FullNamedExpression {
public override FullNamedExpression ResolveAsTypeStep (IMemberContext ec, bool silent)
{
TypeExpr t = DoResolveAsTypeStep (ec);
if (t == null)
return null;
eclass = ExprClass.Type;
return t;
}
protected override Expression DoResolve (ResolveContext ec)
{
return ResolveAsTypeTerminal (ec, false);
}
public virtual bool CheckAccessLevel (IMemberContext mc)
{
DeclSpace c = mc.CurrentMemberDefinition as DeclSpace;
if (c == null)
c = mc.CurrentMemberDefinition.Parent;
return c.CheckAccessLevel (Type);
}
protected abstract TypeExpr DoResolveAsTypeStep (IMemberContext ec);
public override bool Equals (object obj)
{
TypeExpr tobj = obj as TypeExpr;
if (tobj == null)
return false;
return Type == tobj.Type;
}
public override int GetHashCode ()
{
return Type.GetHashCode ();
}
}
///
/// Fully resolved Expression that already evaluated to a type
///
public class TypeExpression : TypeExpr {
public TypeExpression (TypeSpec t, Location l)
{
Type = t;
eclass = ExprClass.Type;
loc = l;
}
protected override TypeExpr DoResolveAsTypeStep (IMemberContext ec)
{
return this;
}
public override TypeExpr ResolveAsTypeTerminal (IMemberContext ec, bool silent)
{
return this;
}
}
///
/// This class denotes an expression which evaluates to a member
/// of a struct or a class.
///
public abstract class MemberExpr : Expression
{
//
// An instance expression associated with this member, if it's a
// non-static member
//
public Expression InstanceExpression;
///
/// The name of this member.
///
public abstract string Name {
get;
}
//
// When base.member is used
//
public bool IsBase {
get { return InstanceExpression is BaseThis; }
}
///
/// Whether this is an instance member.
///
public abstract bool IsInstance {
get;
}
///
/// Whether this is a static member.
///
public abstract bool IsStatic {
get;
}
///
/// The type which declares this member.
///
public abstract TypeSpec DeclaringType {
get;
}
//
// Converts best base candidate for virtual method starting from QueriedBaseType
//
protected MethodSpec CandidateToBaseOverride (ResolveContext rc, MethodSpec method)
{
//
// Only when base.member is used and method is virtual
//
if (!IsBase || method.DeclaringType == InstanceExpression.Type)
return method;
//
// Overload resulution works on virtual or non-virtual members only (no overrides). That
// means for base.member access we have to find the closest match after we found best candidate
//
if ((method.Modifiers & (Modifiers.ABSTRACT | Modifiers.VIRTUAL | Modifiers.STATIC)) != Modifiers.STATIC) {
var base_override = MemberCache.FindMember (InstanceExpression.Type, new MemberFilter (method), BindingRestriction.InstanceOnly) as MethodSpec;
if (base_override != null && base_override.DeclaringType != method.DeclaringType) {
if (base_override.IsGeneric)
base_override = base_override.MakeGenericMethod (method.TypeArguments);
if (rc.CurrentAnonymousMethod != null)
throw new NotImplementedException ("base call hoisting");
return base_override;
}
}
return method;
}
//
// Implements identicial simple name and type-name
//
public Expression ProbeIdenticalTypeName (ResolveContext rc, Expression left, SimpleName name)
{
var t = left.Type;
if (t.Kind == MemberKind.InternalCompilerType || t is ElementTypeSpec || t.Arity > 0)
return left;
// In a member access of the form E.I, if E is a single identifier, and if the meaning of E as a simple-name is
// a constant, field, property, local variable, or parameter with the same type as the meaning of E as a type-name
if (left is MemberExpr || left is VariableReference) {
rc.Report.DisableReporting ();
Expression identical_type = rc.LookupNamespaceOrType (name.Name, 0, loc, true) as TypeExpr;
rc.Report.EnableReporting ();
if (identical_type != null && identical_type.Type == left.Type)
return identical_type;
}
return left;
}
protected bool ResolveInstanceExpression (ResolveContext rc)
{
if (IsStatic) {
if (InstanceExpression != null) {
if (InstanceExpression is TypeExpr) {
ObsoleteAttribute oa = InstanceExpression.Type.GetAttributeObsolete ();
if (oa != null && !rc.IsObsolete) {
AttributeTester.Report_ObsoleteMessage (oa, InstanceExpression.GetSignatureForError (), loc, rc.Report);
}
} else {
var runtime_expr = InstanceExpression as RuntimeValueExpression;
if (runtime_expr == null || !runtime_expr.IsSuggestionOnly) {
rc.Report.Error (176, loc,
"Static member `{0}' cannot be accessed with an instance reference, qualify it with a type name instead",
GetSignatureForError ());
}
}
InstanceExpression = null;
}
return false;
}
if (InstanceExpression == null || InstanceExpression is TypeExpr) {
if (InstanceExpression != null || !This.IsThisAvailable (rc, true)) {
if (rc.HasSet (ResolveContext.Options.FieldInitializerScope))
rc.Report.Error (236, loc,
"A field initializer cannot reference the nonstatic field, method, or property `{0}'",
GetSignatureForError ());
else
rc.Report.Error (120, loc,
"An object reference is required to access non-static member `{0}'",
GetSignatureForError ());
return false;
}
if (!TypeManager.IsFamilyAccessible (rc.CurrentType, DeclaringType)) {
rc.Report.Error (38, loc,
"Cannot access a nonstatic member of outer type `{0}' via nested type `{1}'",
DeclaringType.GetSignatureForError (), rc.CurrentType.GetSignatureForError ());
}
InstanceExpression = rc.GetThis (loc);
return false;
}
var me = InstanceExpression as MemberExpr;
if (me != null)
me.ResolveInstanceExpression (rc);
return true;
}
public virtual MemberExpr ResolveMemberAccess (ResolveContext ec, Expression left, SimpleName original)
{
if (left != null && left.IsNull && TypeManager.IsReferenceType (left.Type)) {
ec.Report.Warning (1720, 1, left.Location,
"Expression will always cause a `{0}'", "System.NullReferenceException");
}
InstanceExpression = left;
return this;
}
protected void EmitInstance (EmitContext ec, bool prepare_for_load)
{
if (TypeManager.IsValueType (InstanceExpression.Type)) {
if (InstanceExpression is IMemoryLocation) {
((IMemoryLocation) InstanceExpression).AddressOf (ec, AddressOp.LoadStore);
} else {
LocalTemporary t = new LocalTemporary (InstanceExpression.Type);
InstanceExpression.Emit (ec);
t.Store (ec);
t.AddressOf (ec, AddressOp.Store);
}
} else
InstanceExpression.Emit (ec);
if (prepare_for_load)
ec.Emit (OpCodes.Dup);
}
public virtual void SetTypeArguments (ResolveContext ec, TypeArguments ta)
{
// TODO: need to get correct member type
ec.Report.Error (307, loc, "The property `{0}' cannot be used with type arguments",
GetSignatureForError ());
}
}
///
/// Represents group of extension methods
///
public class ExtensionMethodGroupExpr : MethodGroupExpr
{
readonly NamespaceEntry namespace_entry;
public Expression ExtensionExpression;
public ExtensionMethodGroupExpr (List list, NamespaceEntry n, TypeSpec extensionType, Location l)
: base (list.Cast().ToList (), extensionType, l)
{
this.namespace_entry = n;
}
public override bool IsStatic {
get { return true; }
}
public bool IsTopLevel {
get { return namespace_entry == null; }
}
public override MethodGroupExpr OverloadResolve (ResolveContext ec, ref Arguments arguments, bool may_fail, Location loc)
{
if (arguments == null)
arguments = new Arguments (1);
arguments.Insert (0, new Argument (ExtensionExpression));
MethodGroupExpr mg = ResolveOverloadExtensions (ec, ref arguments, namespace_entry, loc);
// Store resolved argument and restore original arguments
if (mg == null)
arguments.RemoveAt (0); // Clean-up modified arguments for error reporting
return mg;
}
MethodGroupExpr ResolveOverloadExtensions (ResolveContext ec, ref Arguments arguments, NamespaceEntry ns, Location loc)
{
// Use normal resolve rules
MethodGroupExpr mg = base.OverloadResolve (ec, ref arguments, ns != null, loc);
if (mg != null)
return mg;
if (ns == null)
return null;
// Search continues
int arity = type_arguments == null ? -1 : type_arguments.Count;
ExtensionMethodGroupExpr e = ns.LookupExtensionMethod (type, Name, arity, loc);
if (e == null)
return base.OverloadResolve (ec, ref arguments, false, loc);
e.ExtensionExpression = ExtensionExpression;
e.SetTypeArguments (ec, type_arguments);
return e.ResolveOverloadExtensions (ec, ref arguments, e.namespace_entry, loc);
}
}
///
/// MethodGroupExpr represents a group of method candidates which
/// can be resolved to the best method overload
///
public class MethodGroupExpr : MemberExpr
{
public interface IErrorHandler
{
bool AmbiguousCall (ResolveContext ec, MethodGroupExpr mg, MethodSpec ambiguous);
bool NoExactMatch (ResolveContext ec, MethodSpec method);
}
public IErrorHandler CustomErrorHandler;
protected IList Methods;
MethodSpec best_candidate;
// TODO: make private
public TypeArguments type_arguments;
SimpleName simple_name;
bool has_inaccessible_candidates_only;
TypeSpec delegate_type;
TypeSpec queried_type;
public MethodGroupExpr (IList mi, TypeSpec type, Location l)
: this (type, l)
{
Methods = mi;
}
public MethodGroupExpr (MethodSpec m, TypeSpec type, Location l)
: this (type, l)
{
Methods = new List (1) { m };
}
public MethodGroupExpr (IList mi, TypeSpec type, Location l, bool inacessibleCandidatesOnly)
: this (mi, type, l)
{
has_inaccessible_candidates_only = inacessibleCandidatesOnly;
}
protected MethodGroupExpr (TypeSpec type, Location loc)
{
this.loc = loc;
eclass = ExprClass.MethodGroup;
this.type = InternalType.MethodGroup;
queried_type = type;
}
#region Properties
public MethodSpec BestCandidate {
get {
return best_candidate;
}
}
public override TypeSpec DeclaringType {
get {
return queried_type;
}
}
public TypeSpec DelegateType {
set {
delegate_type = value;
}
}
public override bool IsInstance {
get {
if (best_candidate != null)
return !best_candidate.IsStatic;
return false;
}
}
public override bool IsStatic {
get {
if (best_candidate != null)
return best_candidate.IsStatic;
return false;
}
}
public override string Name {
get {
if (best_candidate != null)
return best_candidate.Name;
// TODO: throw ?
return Methods.First ().Name;
}
}
#endregion
//
// When best candidate is already know this factory can be used
// to avoid expensive overload resolution to be called
//
// NOTE: InstanceExpression has to be set manually
//
public static MethodGroupExpr CreatePredefined (MethodSpec best, TypeSpec queriedType, Location loc)
{
return new MethodGroupExpr (best, queriedType, loc) {
best_candidate = best
};
}
public override string GetSignatureForError ()
{
if (best_candidate != null)
return best_candidate.GetSignatureForError ();
return Methods.First ().GetSignatureForError ();
}
//
// 7.4.3.3 Better conversion from expression
// Returns : 1 if a->p is better,
// 2 if a->q is better,
// 0 if neither is better
//
static int BetterExpressionConversion (ResolveContext ec, Argument a, TypeSpec p, TypeSpec q)
{
TypeSpec argument_type = a.Type;
if (argument_type == InternalType.AnonymousMethod && RootContext.Version > LanguageVersion.ISO_2) {
//
// Uwrap delegate from Expression
//
if (p.GetDefinition () == TypeManager.expression_type) {
p = TypeManager.GetTypeArguments (p) [0];
}
if (q.GetDefinition () == TypeManager.expression_type) {
q = TypeManager.GetTypeArguments (q) [0];
}
p = Delegate.GetInvokeMethod (ec.Compiler, p).ReturnType;
q = Delegate.GetInvokeMethod (ec.Compiler, q).ReturnType;
if (p == TypeManager.void_type && q != TypeManager.void_type)
return 2;
if (q == TypeManager.void_type && p != TypeManager.void_type)
return 1;
} else {
if (argument_type == p)
return 1;
if (argument_type == q)
return 2;
}
return BetterTypeConversion (ec, p, q);
}
//
// 7.4.3.4 Better conversion from type
//
public static int BetterTypeConversion (ResolveContext ec, TypeSpec p, TypeSpec q)
{
if (p == null || q == null)
throw new InternalErrorException ("BetterTypeConversion got a null conversion");
if (p == TypeManager.int32_type) {
if (q == TypeManager.uint32_type || q == TypeManager.uint64_type)
return 1;
} else if (p == TypeManager.int64_type) {
if (q == TypeManager.uint64_type)
return 1;
} else if (p == TypeManager.sbyte_type) {
if (q == TypeManager.byte_type || q == TypeManager.ushort_type ||
q == TypeManager.uint32_type || q == TypeManager.uint64_type)
return 1;
} else if (p == TypeManager.short_type) {
if (q == TypeManager.ushort_type || q == TypeManager.uint32_type ||
q == TypeManager.uint64_type)
return 1;
} else if (p == InternalType.Dynamic) {
if (q == TypeManager.object_type)
return 2;
}
if (q == TypeManager.int32_type) {
if (p == TypeManager.uint32_type || p == TypeManager.uint64_type)
return 2;
} if (q == TypeManager.int64_type) {
if (p == TypeManager.uint64_type)
return 2;
} else if (q == TypeManager.sbyte_type) {
if (p == TypeManager.byte_type || p == TypeManager.ushort_type ||
p == TypeManager.uint32_type || p == TypeManager.uint64_type)
return 2;
} if (q == TypeManager.short_type) {
if (p == TypeManager.ushort_type || p == TypeManager.uint32_type ||
p == TypeManager.uint64_type)
return 2;
} else if (q == InternalType.Dynamic) {
if (p == TypeManager.object_type)
return 1;
}
// TODO: this is expensive
Expression p_tmp = new EmptyExpression (p);
Expression q_tmp = new EmptyExpression (q);
bool p_to_q = Convert.ImplicitConversionExists (ec, p_tmp, q);
bool q_to_p = Convert.ImplicitConversionExists (ec, q_tmp, p);
if (p_to_q && !q_to_p)
return 1;
if (q_to_p && !p_to_q)
return 2;
return 0;
}
///
/// Determines "Better function" between candidate
/// and the current best match
///
///
/// Returns a boolean indicating :
/// false if candidate ain't better
/// true if candidate is better than the current best match
///
static bool BetterFunction (ResolveContext ec, Arguments args, int argument_count,
MethodSpec candidate, bool candidate_params,
MethodSpec best, bool best_params)
{
AParametersCollection candidate_pd = candidate.Parameters;
AParametersCollection best_pd = best.Parameters;
bool better_at_least_one = false;
bool same = true;
for (int j = 0, c_idx = 0, b_idx = 0; j < argument_count; ++j, ++c_idx, ++b_idx)
{
Argument a = args [j];
// Provided default argument value is never better
if (a.IsDefaultArgument && candidate_params == best_params)
return false;
TypeSpec ct = candidate_pd.Types [c_idx];
TypeSpec bt = best_pd.Types [b_idx];
if (candidate_params && candidate_pd.FixedParameters [c_idx].ModFlags == Parameter.Modifier.PARAMS)
{
ct = TypeManager.GetElementType (ct);
--c_idx;
}
if (best_params && best_pd.FixedParameters [b_idx].ModFlags == Parameter.Modifier.PARAMS)
{
bt = TypeManager.GetElementType (bt);
--b_idx;
}
if (TypeManager.IsEqual (ct, bt))
continue;
same = false;
int result = BetterExpressionConversion (ec, a, ct, bt);
// for each argument, the conversion to 'ct' should be no worse than
// the conversion to 'bt'.
if (result == 2)
return false;
// for at least one argument, the conversion to 'ct' should be better than
// the conversion to 'bt'.
if (result != 0)
better_at_least_one = true;
}
if (better_at_least_one)
return true;
//
// This handles the case
//
// Add (float f1, float f2, float f3);
// Add (params decimal [] foo);
//
// The call Add (3, 4, 5) should be ambiguous. Without this check, the
// first candidate would've chosen as better.
//
if (!same)
return false;
//
// The two methods have equal parameter types. Now apply tie-breaking rules
//
if (best.IsGeneric) {
if (!candidate.IsGeneric)
return true;
} else if (candidate.IsGeneric) {
return false;
}
//
// This handles the following cases:
//
// Trim () is better than Trim (params char[] chars)
// Concat (string s1, string s2, string s3) is better than
// Concat (string s1, params string [] srest)
// Foo (int, params int [] rest) is better than Foo (params int [] rest)
//
if (!candidate_params && best_params)
return true;
if (candidate_params && !best_params)
return false;
int candidate_param_count = candidate_pd.Count;
int best_param_count = best_pd.Count;
if (candidate_param_count != best_param_count)
// can only happen if (candidate_params && best_params)
return candidate_param_count > best_param_count && best_pd.HasParams;
//
// Both methods have the same number of parameters, and the parameters have equal types
// Pick the "more specific" signature using rules over original (non-inflated) types
//
var candidate_def_pd = ((IParametersMember) candidate.MemberDefinition).Parameters;
var best_def_pd = ((IParametersMember) best.MemberDefinition).Parameters;
bool specific_at_least_once = false;
for (int j = 0; j < candidate_param_count; ++j)
{
var ct = candidate_def_pd.Types [j];
var bt = best_def_pd.Types [j];
if (ct == bt)
continue;
TypeSpec specific = MoreSpecific (ct, bt);
if (specific == bt)
return false;
if (specific == ct)
specific_at_least_once = true;
}
if (specific_at_least_once)
return true;
// FIXME: handle lifted operators
// ...
return false;
}
public override MemberExpr ResolveMemberAccess (ResolveContext ec, Expression left, SimpleName original)
{
simple_name = original;
return base.ResolveMemberAccess (ec, left, original);
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
if (best_candidate == null) {
ec.Report.Error (1953, loc, "An expression tree cannot contain an expression with method group");
return null;
}
if (best_candidate.IsConditionallyExcluded (loc))
ec.Report.Error (765, loc,
"Partial methods with only a defining declaration or removed conditional methods cannot be used in an expression tree");
return new TypeOfMethod (best_candidate, loc);
}
protected override Expression DoResolve (ResolveContext ec)
{
this.eclass = ExprClass.MethodGroup;
if (InstanceExpression != null) {
InstanceExpression = InstanceExpression.Resolve (ec);
if (InstanceExpression == null)
return null;
}
return this;
}
public void ReportUsageError (ResolveContext ec)
{
ec.Report.Error (654, loc, "Method `" + DeclaringType + "." +
Name + "()' is referenced without parentheses");
}
override public void Emit (EmitContext ec)
{
throw new NotSupportedException ();
}
public void EmitCall (EmitContext ec, Arguments arguments)
{
Invocation.EmitCall (ec, InstanceExpression, best_candidate, arguments, loc);
}
void Error_AmbiguousCall (ResolveContext ec, MethodSpec ambiguous)
{
if (CustomErrorHandler != null && CustomErrorHandler.AmbiguousCall (ec, this, ambiguous))
return;
ec.Report.SymbolRelatedToPreviousError (best_candidate);
ec.Report.Error (121, loc, "The call is ambiguous between the following methods or properties: `{0}' and `{1}'",
best_candidate.GetSignatureForError (), ambiguous.GetSignatureForError ());
}
protected virtual void Error_InvalidArguments (ResolveContext ec, Location loc, int idx, MethodSpec method,
Argument a, AParametersCollection expected_par, TypeSpec paramType)
{
ExtensionMethodGroupExpr emg = this as ExtensionMethodGroupExpr;
if (a is CollectionElementInitializer.ElementInitializerArgument) {
ec.Report.SymbolRelatedToPreviousError (method);
if ((expected_par.FixedParameters [idx].ModFlags & Parameter.Modifier.ISBYREF) != 0) {
ec.Report.Error (1954, loc, "The best overloaded collection initalizer method `{0}' cannot have 'ref', or `out' modifier",
TypeManager.CSharpSignature (method));
return;
}
ec.Report.Error (1950, loc, "The best overloaded collection initalizer method `{0}' has some invalid arguments",
TypeManager.CSharpSignature (method));
} else if (TypeManager.IsDelegateType (method.DeclaringType)) {
ec.Report.Error (1594, loc, "Delegate `{0}' has some invalid arguments",
TypeManager.CSharpName (method.DeclaringType));
} else {
ec.Report.SymbolRelatedToPreviousError (method);
if (emg != null) {
ec.Report.Error (1928, loc,
"Type `{0}' does not contain a member `{1}' and the best extension method overload `{2}' has some invalid arguments",
emg.ExtensionExpression.GetSignatureForError (),
emg.Name, TypeManager.CSharpSignature (method));
} else {
ec.Report.Error (1502, loc, "The best overloaded method match for `{0}' has some invalid arguments",
TypeManager.CSharpSignature (method));
}
}
Parameter.Modifier mod = idx >= expected_par.Count ? 0 : expected_par.FixedParameters [idx].ModFlags;
string index = (idx + 1).ToString ();
if (((mod & (Parameter.Modifier.REF | Parameter.Modifier.OUT)) ^
(a.Modifier & (Parameter.Modifier.REF | Parameter.Modifier.OUT))) != 0) {
if ((mod & Parameter.Modifier.ISBYREF) == 0)
ec.Report.Error (1615, loc, "Argument `#{0}' does not require `{1}' modifier. Consider removing `{1}' modifier",
index, Parameter.GetModifierSignature (a.Modifier));
else
ec.Report.Error (1620, loc, "Argument `#{0}' is missing `{1}' modifier",
index, Parameter.GetModifierSignature (mod));
} else {
string p1 = a.GetSignatureForError ();
string p2 = TypeManager.CSharpName (paramType);
if (p1 == p2) {
ec.Report.ExtraInformation (loc, "(equally named types possibly from different assemblies in previous ");
ec.Report.SymbolRelatedToPreviousError (a.Expr.Type);
ec.Report.SymbolRelatedToPreviousError (paramType);
}
if (idx == 0 && emg != null) {
ec.Report.Error (1929, loc,
"Extension method instance type `{0}' cannot be converted to `{1}'", p1, p2);
} else {
ec.Report.Error (1503, loc,
"Argument `#{0}' cannot convert `{1}' expression to type `{2}'", index, p1, p2);
}
}
}
public override void Error_ValueCannotBeConverted (ResolveContext ec, Location loc, TypeSpec target, bool expl)
{
ec.Report.Error (428, loc, "Cannot convert method group `{0}' to non-delegate type `{1}'. Consider using parentheses to invoke the method",
Name, TypeManager.CSharpName (target));
}
void Error_ArgumentCountWrong (ResolveContext ec, int arg_count)
{
ec.Report.Error (1501, loc, "No overload for method `{0}' takes `{1}' arguments",
Name, arg_count.ToString ());
}
protected virtual int GetApplicableParametersCount (MethodSpec method, AParametersCollection parameters)
{
return parameters.Count;
}
protected virtual IList GetBaseTypeMethods (ResolveContext rc, TypeSpec type)
{
var arity = type_arguments == null ? -1 : type_arguments.Count;
return TypeManager.MemberLookup (rc.CurrentType, null, type,
MemberKind.Method, BindingRestriction.AccessibleOnly | BindingRestriction.DefaultMemberLookup,
Name, arity, null);
}
bool GetBaseTypeMethods (ResolveContext rc)
{
var base_type = Methods [0].DeclaringType.BaseType;
if (base_type == null)
return false;
var methods = GetBaseTypeMethods (rc, base_type);
if (methods == null)
return false;
Methods = methods;
return true;
}
///
/// Determines if the candidate method is applicable (section 14.4.2.1)
/// to the given set of arguments
/// A return value rates candidate method compatibility,
/// 0 = the best, int.MaxValue = the worst
///
public int IsApplicable (ResolveContext ec,
ref Arguments arguments, int arg_count, ref MethodSpec method, ref bool params_expanded_form)
{
var candidate = method;
AParametersCollection pd = candidate.Parameters;
int param_count = GetApplicableParametersCount (candidate, pd);
int optional_count = 0;
if (arg_count != param_count) {
for (int i = 0; i < pd.Count; ++i) {
if (pd.FixedParameters [i].HasDefaultValue) {
optional_count = pd.Count - i;
break;
}
}
int args_gap = System.Math.Abs (arg_count - param_count);
if (optional_count != 0) {
if (args_gap > optional_count)
return int.MaxValue - 10000 + args_gap - optional_count;
// Readjust expected number when params used
if (pd.HasParams) {
optional_count--;
if (arg_count < param_count)
param_count--;
} else if (arg_count > param_count) {
return int.MaxValue - 10000 + args_gap;
}
} else if (arg_count != param_count) {
if (!pd.HasParams)
return int.MaxValue - 10000 + args_gap;
if (arg_count < param_count - 1)
return int.MaxValue - 10000 + args_gap;
}
// Initialize expanded form of a method with 1 params parameter
params_expanded_form = param_count == 1 && pd.HasParams;
// Resize to fit optional arguments
if (optional_count != 0) {
Arguments resized;
if (arguments == null) {
resized = new Arguments (optional_count);
} else {
resized = new Arguments (param_count);
resized.AddRange (arguments);
}
for (int i = arg_count; i < param_count; ++i)
resized.Add (null);
arguments = resized;
}
}
if (arg_count > 0) {
//
// Shuffle named arguments to the right positions if there are any
//
if (arguments [arg_count - 1] is NamedArgument) {
arg_count = arguments.Count;
for (int i = 0; i < arg_count; ++i) {
bool arg_moved = false;
while (true) {
NamedArgument na = arguments[i] as NamedArgument;
if (na == null)
break;
int index = pd.GetParameterIndexByName (na.Name);
// Named parameter not found or already reordered
if (index <= i)
break;
// When using parameters which should not be available to the user
if (index >= param_count)
break;
if (!arg_moved) {
arguments.MarkReorderedArgument (na);
arg_moved = true;
}
Argument temp = arguments[index];
arguments[index] = arguments[i];
arguments[i] = temp;
if (temp == null)
break;
}
}
} else {
arg_count = arguments.Count;
}
} else if (arguments != null) {
arg_count = arguments.Count;
}
//
// 1. Handle generic method using type arguments when specified or type inference
//
if (candidate.IsGeneric) {
if (type_arguments != null) {
var g_args_count = candidate.Arity;
if (g_args_count != type_arguments.Count)
return int.MaxValue - 20000 + System.Math.Abs (type_arguments.Count - g_args_count);
method = candidate.MakeGenericMethod (type_arguments.Arguments);
candidate = method;
pd = candidate.Parameters;
} else {
int score = TypeManager.InferTypeArguments (ec, arguments, ref candidate);
if (score != 0)
return score - 20000;
pd = candidate.Parameters;
}
} else {
if (type_arguments != null)
return int.MaxValue - 15000;
}
//
// 2. Each argument has to be implicitly convertible to method parameter
//
method = candidate;
Parameter.Modifier p_mod = 0;
TypeSpec pt = null;
for (int i = 0; i < arg_count; i++) {
Argument a = arguments [i];
if (a == null) {
if (!pd.FixedParameters [i].HasDefaultValue)
throw new InternalErrorException ();
Expression e = pd.FixedParameters [i].DefaultValue as Constant;
if (e == null)
e = new DefaultValueExpression (new TypeExpression (pd.Types [i], loc), loc).Resolve (ec);
arguments [i] = new Argument (e, Argument.AType.Default);
continue;
}
if (p_mod != Parameter.Modifier.PARAMS) {
p_mod = pd.FixedParameters [i].ModFlags & ~(Parameter.Modifier.OUTMASK | Parameter.Modifier.REFMASK);
pt = pd.Types [i];
} else {
params_expanded_form = true;
}
Parameter.Modifier a_mod = a.Modifier & ~(Parameter.Modifier.OUTMASK | Parameter.Modifier.REFMASK);
int score = 1;
if (!params_expanded_form)
score = IsArgumentCompatible (ec, a_mod, a, p_mod & ~Parameter.Modifier.PARAMS, pt);
if (score != 0 && (p_mod & Parameter.Modifier.PARAMS) != 0 && delegate_type == null) {
// It can be applicable in expanded form
score = IsArgumentCompatible (ec, a_mod, a, 0, TypeManager.GetElementType (pt));
if (score == 0)
params_expanded_form = true;
}
if (score != 0) {
if (params_expanded_form)
++score;
return (arg_count - i) * 2 + score;
}
}
if (arg_count != param_count)
params_expanded_form = true;
return 0;
}
int IsArgumentCompatible (ResolveContext ec, Parameter.Modifier arg_mod, Argument argument, Parameter.Modifier param_mod, TypeSpec parameter)
{
//
// Types have to be identical when ref or out modifer is used
//
if (arg_mod != 0 || param_mod != 0) {
if (argument.Type != parameter) {
if (argument.Type == InternalType.Dynamic)
return 0;
return 2;
}
} else {
if (!Convert.ImplicitConversionExists (ec, argument.Expr, parameter)) {
if (argument.Type == InternalType.Dynamic)
return 0;
return 2;
}
}
if (arg_mod != param_mod)
return 1;
return 0;
}
static TypeSpec MoreSpecific (TypeSpec p, TypeSpec q)
{
if (TypeManager.IsGenericParameter (p) && !TypeManager.IsGenericParameter (q))
return q;
if (!TypeManager.IsGenericParameter (p) && TypeManager.IsGenericParameter (q))
return p;
var ac_p = p as ArrayContainer;
if (ac_p != null) {
var ac_q = ((ArrayContainer) q);
TypeSpec specific = MoreSpecific (ac_p.Element, (ac_q.Element));
if (specific == ac_p.Element)
return p;
if (specific == ac_q.Element)
return q;
} else if (TypeManager.IsGenericType (p)) {
var pargs = TypeManager.GetTypeArguments (p);
var qargs = TypeManager.GetTypeArguments (q);
bool p_specific_at_least_once = false;
bool q_specific_at_least_once = false;
for (int i = 0; i < pargs.Length; i++) {
TypeSpec specific = MoreSpecific (pargs[i], qargs[i]);
if (specific == pargs[i])
p_specific_at_least_once = true;
if (specific == qargs[i])
q_specific_at_least_once = true;
}
if (p_specific_at_least_once && !q_specific_at_least_once)
return p;
if (!p_specific_at_least_once && q_specific_at_least_once)
return q;
}
return null;
}
///
/// Find the Applicable Function Members (7.4.2.1)
///
/// me: Method Group expression with the members to select.
/// it might contain constructors or methods (or anything
/// that maps to a method).
///
/// Arguments: ArrayList containing resolved Argument objects.
///
/// loc: The location if we want an error to be reported, or a Null
/// location for "probing" purposes.
///
/// Returns: The MethodBase (either a ConstructorInfo or a MethodInfo)
/// that is the best match of me on Arguments.
///
///
public virtual MethodGroupExpr OverloadResolve (ResolveContext ec, ref Arguments Arguments,
bool may_fail, Location loc)
{
// TODO: causes some issues with linq
//if (best_candidate != null)
// return this;
var candidates = new List (2);
List params_candidates = null;
int arg_count = Arguments != null ? Arguments.Count : 0;
Dictionary candidates_expanded = null;
Arguments candidate_args = Arguments;
if (RootContext.Version == LanguageVersion.ISO_1 && Name == "Invoke" && TypeManager.IsDelegateType (DeclaringType)) {
if (!may_fail)
ec.Report.Error (1533, loc, "Invoke cannot be called directly on a delegate");
return null;
}
//
// Enable message recording, it's used mainly by lambda expressions
//
var msg_recorder = new SessionReportPrinter ();
var prev_recorder = ec.Report.SetPrinter (msg_recorder);
try {
do {
//
// Methods in a base class are not candidates if any method in a derived
// class is applicable
//
int best_candidate_rate = int.MaxValue;
foreach (var member in Methods) {
var m = member as MethodSpec;
if (m == null) {
// TODO: It's wrong when non-member is before applicable method
// TODO: Should report only when at least 1 from the batch is applicable
if (candidates.Count != 0) {
ec.Report.SymbolRelatedToPreviousError (candidates[0]);
ec.Report.SymbolRelatedToPreviousError (member);
ec.Report.Warning (467, 2, loc, "Ambiguity between method `{0}' and non-method `{1}'. Using method `{0}'",
candidates[0].GetSignatureForError (), member.GetSignatureForError ());
}
continue;
}
//
// Check if candidate is applicable (section 14.4.2.1)
//
bool params_expanded_form = false;
int candidate_rate = IsApplicable (ec, ref candidate_args, arg_count, ref m, ref params_expanded_form);
if (candidate_rate < best_candidate_rate) {
best_candidate_rate = candidate_rate;
best_candidate = m;
}
if (params_expanded_form) {
if (params_candidates == null)
params_candidates = new List (2);
params_candidates.Add (m);
}
if (candidate_args != Arguments) {
if (candidates_expanded == null)
candidates_expanded = new Dictionary (2);
candidates_expanded.Add (m, candidate_args);
candidate_args = Arguments;
}
if (candidate_rate != 0 || has_inaccessible_candidates_only) {
if (msg_recorder != null)
msg_recorder.EndSession ();
continue;
}
msg_recorder = null;
candidates.Add (m);
}
} while (candidates.Count == 0 && GetBaseTypeMethods (ec));
} finally {
ec.Report.SetPrinter (prev_recorder);
}
int candidate_top = candidates.Count;
if (candidate_top == 0) {
//
// When we found a top level method which does not match and it's
// not an extension method. We start extension methods lookup from here
//
if (InstanceExpression != null) {
var first = Methods.First ();
var arity = type_arguments == null ? -1 : type_arguments.Count;
ExtensionMethodGroupExpr ex_method_lookup = ec.LookupExtensionMethod (type, first.Name, arity, loc);
if (ex_method_lookup != null) {
ex_method_lookup.ExtensionExpression = InstanceExpression.Resolve (ec);
ex_method_lookup.SetTypeArguments (ec, type_arguments);
var emg = ex_method_lookup.OverloadResolve (ec, ref Arguments, may_fail, loc);
if (emg != null)
return emg;
}
}
if (msg_recorder != null && !msg_recorder.IsEmpty) {
if (!may_fail)
msg_recorder.Merge (prev_recorder);
return null;
}
if (may_fail)
return null;
//
// Okay so we have failed to find exact match so we
// return error info about the closest match
//
if (best_candidate != null) {
if (CustomErrorHandler != null && !has_inaccessible_candidates_only && CustomErrorHandler.NoExactMatch (ec, best_candidate))
return null;
bool params_expanded = params_candidates != null && params_candidates.Contains (best_candidate);
if (NoExactMatch (ec, ref Arguments, params_expanded))
return null;
}
//
// We failed to find any method with correct argument count
//
if (Methods.First ().Kind == MemberKind.Constructor) {
ec.Report.SymbolRelatedToPreviousError (queried_type);
ec.Report.Error (1729, loc,
"The type `{0}' does not contain a constructor that takes `{1}' arguments",
TypeManager.CSharpName (queried_type), arg_count.ToString ());
} else {
Error_ArgumentCountWrong (ec, arg_count);
}
return null;
}
if (arg_count != 0 && Arguments.HasDynamic) {
best_candidate = null;
return this;
}
//
// Now we actually find the best method
//
best_candidate = candidates [0];
bool method_params = params_candidates != null && params_candidates.Contains (best_candidate);
for (int ix = 1; ix < candidate_top; ix++) {
var candidate = candidates [ix];
if (candidate == best_candidate)
continue;
bool cand_params = params_candidates != null && params_candidates.Contains (candidate);
if (candidates_expanded != null && candidates_expanded.ContainsKey (candidate)) {
candidate_args = candidates_expanded[candidate];
arg_count = candidate_args.Count;
}
if (BetterFunction (ec, candidate_args, arg_count,
candidate, cand_params,
best_candidate, method_params)) {
best_candidate = candidate;
method_params = cand_params;
}
if (candidate_args != Arguments) {
candidate_args = Arguments;
arg_count = candidate_args != null ? candidate_args.Count : 0;
}
}
if (candidates_expanded != null && candidates_expanded.ContainsKey (best_candidate)) {
candidate_args = candidates_expanded[best_candidate];
arg_count = candidate_args.Count;
}
//
// Now check that there are no ambiguities i.e the selected method
// should be better than all the others
//
MethodSpec ambiguous = null;
for (int ix = 1; ix < candidate_top; ix++) {
var candidate = candidates [ix];
if (candidate == best_candidate)
continue;
bool cand_params = params_candidates != null && params_candidates.Contains (candidate);
if (!BetterFunction (ec, candidate_args, arg_count,
best_candidate, method_params,
candidate, cand_params))
{
if (!may_fail)
ec.Report.SymbolRelatedToPreviousError (candidate);
ambiguous = candidate;
}
}
if (ambiguous != null) {
Error_AmbiguousCall (ec, ambiguous);
return this;
}
best_candidate = CandidateToBaseOverride (ec, best_candidate);
//
// And now check if the arguments are all
// compatible, perform conversions if
// necessary etc. and return if everything is
// all right
//
if (!VerifyArgumentsCompat (ec, ref candidate_args, arg_count, best_candidate,
method_params, may_fail, loc))
return null;
if (best_candidate == null)
return null;
if (best_candidate.Kind == MemberKind.Method) {
if (InstanceExpression != null) {
if (best_candidate.IsStatic && simple_name != null) {
InstanceExpression = ProbeIdenticalTypeName (ec, InstanceExpression, simple_name);
}
InstanceExpression.Resolve (ec);
}
ResolveInstanceExpression (ec);
}
if (best_candidate.IsGeneric) {
ConstraintChecker.CheckAll (ec, best_candidate.GetGenericMethodDefinition (), best_candidate.TypeArguments,
best_candidate.Constraints, loc);
}
//
// Check ObsoleteAttribute on the best method
//
ObsoleteAttribute oa = best_candidate.GetAttributeObsolete ();
if (oa != null && !ec.IsObsolete)
AttributeTester.Report_ObsoleteMessage (oa, GetSignatureForError (), loc, ec.Report);
best_candidate.MemberDefinition.SetIsUsed ();
Arguments = candidate_args;
return this;
}
bool NoExactMatch (ResolveContext ec, ref Arguments Arguments, bool params_expanded)
{
AParametersCollection pd = best_candidate.Parameters;
int arg_count = Arguments == null ? 0 : Arguments.Count;
if (arg_count == pd.Count || pd.HasParams) {
if (best_candidate.IsGeneric) {
if (type_arguments == null) {
ec.Report.Error (411, loc,
"The type arguments for method `{0}' cannot be inferred from the usage. Try specifying the type arguments explicitly",
best_candidate.GetGenericMethodDefinition().GetSignatureForError ());
return true;
}
}
var ta = type_arguments == null ? 0 : type_arguments.Count;
if (ta != best_candidate.Arity) {
Error_TypeArgumentsCannotBeUsed (ec.Report, loc, best_candidate, type_arguments.Count);
return true;
}
if (has_inaccessible_candidates_only) {
if (InstanceExpression != null && type != ec.CurrentType && TypeManager.IsNestedFamilyAccessible (ec.CurrentType, best_candidate.DeclaringType)) {
// Although a derived class can access protected members of
// its base class it cannot do so through an instance of the
// base class (CS1540). If the qualifier_type is a base of the
// ec.CurrentType and the lookup succeeds with the latter one,
// then we are in this situation.
Error_CannotAccessProtected (ec, loc, best_candidate, queried_type, ec.CurrentType);
} else {
ec.Report.SymbolRelatedToPreviousError (best_candidate);
ErrorIsInaccesible (loc, GetSignatureForError (), ec.Report);
}
}
if (!VerifyArgumentsCompat (ec, ref Arguments, arg_count, best_candidate, params_expanded, false, loc))
return true;
if (has_inaccessible_candidates_only)
return true;
}
return false;
}
public override void SetTypeArguments (ResolveContext ec, TypeArguments ta)
{
type_arguments = ta;
}
public bool VerifyArgumentsCompat (ResolveContext ec, ref Arguments arguments,
int arg_count, MethodSpec method,
bool chose_params_expanded,
bool may_fail, Location loc)
{
AParametersCollection pd = method.Parameters;
int param_count = GetApplicableParametersCount (method, pd);
int errors = ec.Report.Errors;
Parameter.Modifier p_mod = 0;
TypeSpec pt = null;
int a_idx = 0, a_pos = 0;
Argument a = null;
ArrayInitializer params_initializers = null;
bool has_unsafe_arg = method.ReturnType.IsPointer;
for (; a_idx < arg_count; a_idx++, ++a_pos) {
a = arguments [a_idx];
if (p_mod != Parameter.Modifier.PARAMS) {
p_mod = pd.FixedParameters [a_idx].ModFlags;
pt = pd.Types [a_idx];
has_unsafe_arg |= pt.IsPointer;
if (p_mod == Parameter.Modifier.PARAMS) {
if (chose_params_expanded) {
params_initializers = new ArrayInitializer (arg_count - a_idx, a.Expr.Location);
pt = TypeManager.GetElementType (pt);
}
}
}
//
// Types have to be identical when ref or out modifer is used
//
if (a.Modifier != 0 || (p_mod & ~Parameter.Modifier.PARAMS) != 0) {
if ((p_mod & ~Parameter.Modifier.PARAMS) != a.Modifier)
break;
if (!TypeManager.IsEqual (a.Expr.Type, pt))
break;
continue;
} else {
NamedArgument na = a as NamedArgument;
if (na != null) {
int name_index = pd.GetParameterIndexByName (na.Name);
if (name_index < 0 || name_index >= param_count) {
if (DeclaringType != null && TypeManager.IsDelegateType (DeclaringType)) {
ec.Report.SymbolRelatedToPreviousError (DeclaringType);
ec.Report.Error (1746, na.Location,
"The delegate `{0}' does not contain a parameter named `{1}'",
TypeManager.CSharpName (DeclaringType), na.Name);
} else {
ec.Report.SymbolRelatedToPreviousError (best_candidate);
ec.Report.Error (1739, na.Location,
"The best overloaded method match for `{0}' does not contain a parameter named `{1}'",
TypeManager.CSharpSignature (method), na.Name);
}
} else if (arguments[name_index] != a) {
if (DeclaringType != null && TypeManager.IsDelegateType (DeclaringType))
ec.Report.SymbolRelatedToPreviousError (DeclaringType);
else
ec.Report.SymbolRelatedToPreviousError (best_candidate);
ec.Report.Error (1744, na.Location,
"Named argument `{0}' cannot be used for a parameter which has positional argument specified",
na.Name);
}
}
}
if (a.Expr.Type == InternalType.Dynamic)
continue;
if (delegate_type != null && !Delegate.IsTypeCovariant (a.Expr, pt))
break;
Expression conv = Convert.ImplicitConversion (ec, a.Expr, pt, loc);
if (conv == null)
break;
//
// Convert params arguments to an array initializer
//
if (params_initializers != null) {
// we choose to use 'a.Expr' rather than 'conv' so that
// we don't hide the kind of expression we have (esp. CompoundAssign.Helper)
params_initializers.Add (a.Expr);
arguments.RemoveAt (a_idx--);
--arg_count;
continue;
}
// Update the argument with the implicit conversion
a.Expr = conv;
}
if (a_idx != arg_count) {
if (!may_fail && ec.Report.Errors == errors) {
if (CustomErrorHandler != null)
CustomErrorHandler.NoExactMatch (ec, best_candidate);
else
Error_InvalidArguments (ec, loc, a_pos, method, a, pd, pt);
}
return false;
}
//
// Fill not provided arguments required by params modifier
//
if (params_initializers == null && pd.HasParams && arg_count + 1 == param_count) {
if (arguments == null)
arguments = new Arguments (1);
pt = pd.Types [param_count - 1];
pt = TypeManager.GetElementType (pt);
has_unsafe_arg |= pt.IsPointer;
params_initializers = new ArrayInitializer (0, loc);
}
//
// Append an array argument with all params arguments
//
if (params_initializers != null) {
arguments.Add (new Argument (
new ArrayCreation (new TypeExpression (pt, loc), params_initializers, loc).Resolve (ec)));
arg_count++;
}
if (arg_count < param_count) {
if (!may_fail)
Error_ArgumentCountWrong (ec, arg_count);
return false;
}
if (has_unsafe_arg && !ec.IsUnsafe) {
if (!may_fail)
UnsafeError (ec, loc);
return false;
}
return true;
}
}
public class ConstantExpr : MemberExpr
{
ConstSpec constant;
public ConstantExpr (ConstSpec constant, Location loc)
{
this.constant = constant;
this.loc = loc;
}
public override string Name {
get { throw new NotImplementedException (); }
}
public override bool IsInstance {
get { return !IsStatic; }
}
public override bool IsStatic {
get { return true; }
}
public override TypeSpec DeclaringType {
get { return constant.DeclaringType; }
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
throw new NotSupportedException ("ET");
}
protected override Expression DoResolve (ResolveContext rc)
{
constant.MemberDefinition.SetIsUsed ();
ResolveInstanceExpression (rc);
if (!rc.IsObsolete) {
var oa = constant.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, constant.GetSignatureForError (), loc, rc.Report);
}
var c = constant.GetConstant (rc);
// Creates reference expression to the constant value
return Constant.CreateConstant (rc, constant.MemberType, c.GetValue (), loc);
}
public override void Emit (EmitContext ec)
{
throw new NotSupportedException ();
}
public override string GetSignatureForError ()
{
return constant.GetSignatureForError ();
}
}
///
/// Fully resolved expression that evaluates to a Field
///
public class FieldExpr : MemberExpr, IDynamicAssign, IMemoryLocation, IVariableReference {
protected FieldSpec spec;
VariableInfo variable_info;
LocalTemporary temp;
bool prepared;
protected FieldExpr (Location l)
{
loc = l;
}
public FieldExpr (FieldSpec spec, Location loc)
{
this.spec = spec;
this.loc = loc;
type = spec.MemberType;
}
public FieldExpr (FieldBase fi, Location l)
: this (fi.Spec, l)
{
}
public override string Name {
get {
return spec.Name;
}
}
public override bool IsInstance {
get {
return !spec.IsStatic;
}
}
public override bool IsStatic {
get {
return spec.IsStatic;
}
}
public FieldSpec Spec {
get {
return spec;
}
}
public override TypeSpec DeclaringType {
get {
return spec.DeclaringType;
}
}
public override string GetSignatureForError ()
{
return TypeManager.GetFullNameSignature (spec);
}
public VariableInfo VariableInfo {
get {
return variable_info;
}
}
public void SetHasAddressTaken ()
{
IVariableReference vr = InstanceExpression as IVariableReference;
if (vr != null)
vr.SetHasAddressTaken ();
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
Expression instance;
if (InstanceExpression == null) {
instance = new NullLiteral (loc);
} else {
instance = InstanceExpression.CreateExpressionTree (ec);
}
Arguments args = Arguments.CreateForExpressionTree (ec, null,
instance,
CreateTypeOfExpression ());
return CreateExpressionFactoryCall (ec, "Field", args);
}
public Expression CreateTypeOfExpression ()
{
return new TypeOfField (spec, loc);
}
protected override Expression DoResolve (ResolveContext ec)
{
return DoResolve (ec, false, false);
}
Expression DoResolve (ResolveContext ec, bool lvalue_instance, bool out_access)
{
if (ResolveInstanceExpression (ec)) {
// Resolve the field's instance expression while flow analysis is turned
// off: when accessing a field "a.b", we must check whether the field
// "a.b" is initialized, not whether the whole struct "a" is initialized.
if (lvalue_instance) {
using (ec.With (ResolveContext.Options.DoFlowAnalysis, false)) {
Expression right_side =
out_access ? EmptyExpression.LValueMemberOutAccess : EmptyExpression.LValueMemberAccess;
InstanceExpression = InstanceExpression.ResolveLValue (ec, right_side);
}
} else {
using (ec.With (ResolveContext.Options.DoFlowAnalysis, false)) {
InstanceExpression = InstanceExpression.Resolve (ec, ResolveFlags.VariableOrValue);
}
}
if (InstanceExpression == null)
return null;
using (ec.Set (ResolveContext.Options.OmitStructFlowAnalysis)) {
InstanceExpression.CheckMarshalByRefAccess (ec);
}
}
if (type.IsPointer && !ec.IsUnsafe) {
UnsafeError (ec, loc);
}
if (!ec.IsObsolete) {
ObsoleteAttribute oa = spec.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, TypeManager.GetFullNameSignature (spec), loc, ec.Report);
}
var fb = spec as FixedFieldSpec;
IVariableReference var = InstanceExpression as IVariableReference;
if (lvalue_instance && var != null && var.VariableInfo != null) {
var.VariableInfo.SetFieldAssigned (ec, Name);
}
if (fb != null) {
IFixedExpression fe = InstanceExpression as IFixedExpression;
if (!ec.HasSet (ResolveContext.Options.FixedInitializerScope) && (fe == null || !fe.IsFixed)) {
ec.Report.Error (1666, loc, "You cannot use fixed size buffers contained in unfixed expressions. Try using the fixed statement");
}
if (InstanceExpression.eclass != ExprClass.Variable) {
ec.Report.SymbolRelatedToPreviousError (spec);
ec.Report.Error (1708, loc, "`{0}': Fixed size buffers can only be accessed through locals or fields",
TypeManager.GetFullNameSignature (spec));
} else if (var != null && var.IsHoisted) {
AnonymousMethodExpression.Error_AddressOfCapturedVar (ec, var, loc);
}
return new FixedBufferPtr (this, fb.ElementType, loc).Resolve (ec);
}
eclass = ExprClass.Variable;
// If the instance expression is a local variable or parameter.
if (var == null || var.VariableInfo == null)
return this;
VariableInfo vi = var.VariableInfo;
if (!vi.IsFieldAssigned (ec, Name, loc))
return null;
variable_info = vi.GetSubStruct (Name);
return this;
}
static readonly int [] codes = {
191, // instance, write access
192, // instance, out access
198, // static, write access
199, // static, out access
1648, // member of value instance, write access
1649, // member of value instance, out access
1650, // member of value static, write access
1651 // member of value static, out access
};
static readonly string [] msgs = {
/*0191*/ "A readonly field `{0}' cannot be assigned to (except in a constructor or a variable initializer)",
/*0192*/ "A readonly field `{0}' cannot be passed ref or out (except in a constructor)",
/*0198*/ "A static readonly field `{0}' cannot be assigned to (except in a static constructor or a variable initializer)",
/*0199*/ "A static readonly field `{0}' cannot be passed ref or out (except in a static constructor)",
/*1648*/ "Members of readonly field `{0}' cannot be modified (except in a constructor or a variable initializer)",
/*1649*/ "Members of readonly field `{0}' cannot be passed ref or out (except in a constructor)",
/*1650*/ "Fields of static readonly field `{0}' cannot be assigned to (except in a static constructor or a variable initializer)",
/*1651*/ "Fields of static readonly field `{0}' cannot be passed ref or out (except in a static constructor)"
};
// The return value is always null. Returning a value simplifies calling code.
Expression Report_AssignToReadonly (ResolveContext ec, Expression right_side)
{
int i = 0;
if (right_side == EmptyExpression.OutAccess.Instance || right_side == EmptyExpression.LValueMemberOutAccess)
i += 1;
if (IsStatic)
i += 2;
if (right_side == EmptyExpression.LValueMemberAccess || right_side == EmptyExpression.LValueMemberOutAccess)
i += 4;
ec.Report.Error (codes [i], loc, msgs [i], GetSignatureForError ());
return null;
}
override public Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
bool lvalue_instance = IsInstance && spec.DeclaringType.IsStruct;
bool out_access = right_side == EmptyExpression.OutAccess.Instance || right_side == EmptyExpression.LValueMemberOutAccess;
Expression e = DoResolve (ec, lvalue_instance, out_access);
if (e == null)
return null;
spec.MemberDefinition.SetIsAssigned ();
if ((right_side == EmptyExpression.UnaryAddress || right_side == EmptyExpression.OutAccess.Instance) &&
(spec.Modifiers & Modifiers.VOLATILE) != 0) {
ec.Report.Warning (420, 1, loc,
"`{0}': A volatile field references will not be treated as volatile",
spec.GetSignatureForError ());
}
if (spec.IsReadOnly) {
// InitOnly fields can only be assigned in constructors or initializers
if (!ec.HasAny (ResolveContext.Options.FieldInitializerScope | ResolveContext.Options.ConstructorScope))
return Report_AssignToReadonly (ec, right_side);
if (ec.HasSet (ResolveContext.Options.ConstructorScope)) {
// InitOnly fields cannot be assigned-to in a different constructor from their declaring type
if (!TypeManager.IsEqual (ec.CurrentMemberDefinition.Parent.Definition, DeclaringType.GetDefinition ()))
return Report_AssignToReadonly (ec, right_side);
// static InitOnly fields cannot be assigned-to in an instance constructor
if (IsStatic && !ec.IsStatic)
return Report_AssignToReadonly (ec, right_side);
// instance constructors can't modify InitOnly fields of other instances of the same type
if (!IsStatic && !(InstanceExpression is This))
return Report_AssignToReadonly (ec, right_side);
}
}
if (right_side == EmptyExpression.OutAccess.Instance &&
!IsStatic && !(InstanceExpression is This) && TypeManager.mbr_type != null && TypeManager.IsSubclassOf (DeclaringType, TypeManager.mbr_type)) {
ec.Report.SymbolRelatedToPreviousError (DeclaringType);
ec.Report.Warning (197, 1, loc,
"Passing `{0}' as ref or out or taking its address may cause a runtime exception because it is a field of a marshal-by-reference class",
GetSignatureForError ());
}
eclass = ExprClass.Variable;
return this;
}
bool is_marshal_by_ref ()
{
return !IsStatic && TypeManager.IsStruct (Type) && TypeManager.mbr_type != null && TypeManager.IsSubclassOf (DeclaringType, TypeManager.mbr_type);
}
public override void CheckMarshalByRefAccess (ResolveContext ec)
{
if (is_marshal_by_ref () && !(InstanceExpression is This)) {
ec.Report.SymbolRelatedToPreviousError (DeclaringType);
ec.Report.Warning (1690, 1, loc, "Cannot call methods, properties, or indexers on `{0}' because it is a value type member of a marshal-by-reference class",
GetSignatureForError ());
}
}
public override int GetHashCode ()
{
return spec.GetHashCode ();
}
public bool IsFixed {
get {
//
// A variable of the form V.I is fixed when V is a fixed variable of a struct type
//
IVariableReference variable = InstanceExpression as IVariableReference;
if (variable != null)
return InstanceExpression.Type.IsStruct && variable.IsFixed;
IFixedExpression fe = InstanceExpression as IFixedExpression;
return fe != null && fe.IsFixed;
}
}
public bool IsHoisted {
get {
IVariableReference hv = InstanceExpression as IVariableReference;
return hv != null && hv.IsHoisted;
}
}
public override bool Equals (object obj)
{
FieldExpr fe = obj as FieldExpr;
if (fe == null)
return false;
if (spec != fe.spec)
return false;
if (InstanceExpression == null || fe.InstanceExpression == null)
return true;
return InstanceExpression.Equals (fe.InstanceExpression);
}
public void Emit (EmitContext ec, bool leave_copy)
{
bool is_volatile = false;
if ((spec.Modifiers & Modifiers.VOLATILE) != 0)
is_volatile = true;
spec.MemberDefinition.SetIsUsed ();
if (IsStatic){
if (is_volatile)
ec.Emit (OpCodes.Volatile);
ec.Emit (OpCodes.Ldsfld, spec);
} else {
if (!prepared)
EmitInstance (ec, false);
// Optimization for build-in types
if (TypeManager.IsStruct (type) && TypeManager.IsEqual (type, ec.MemberContext.CurrentType) && TypeManager.IsEqual (InstanceExpression.Type, type)) {
ec.EmitLoadFromPtr (type);
} else {
var ff = spec as FixedFieldSpec;
if (ff != null) {
ec.Emit (OpCodes.Ldflda, spec);
ec.Emit (OpCodes.Ldflda, ff.Element);
} else {
if (is_volatile)
ec.Emit (OpCodes.Volatile);
ec.Emit (OpCodes.Ldfld, spec);
}
}
}
if (leave_copy) {
ec.Emit (OpCodes.Dup);
if (!IsStatic) {
temp = new LocalTemporary (this.Type);
temp.Store (ec);
}
}
}
public void EmitAssign (EmitContext ec, Expression source, bool leave_copy, bool prepare_for_load)
{
prepared = prepare_for_load;
if (IsInstance)
EmitInstance (ec, prepared);
source.Emit (ec);
if (leave_copy) {
ec.Emit (OpCodes.Dup);
if (!IsStatic) {
temp = new LocalTemporary (this.Type);
temp.Store (ec);
}
}
if ((spec.Modifiers & Modifiers.VOLATILE) != 0)
ec.Emit (OpCodes.Volatile);
spec.MemberDefinition.SetIsAssigned ();
if (IsStatic)
ec.Emit (OpCodes.Stsfld, spec);
else
ec.Emit (OpCodes.Stfld, spec);
if (temp != null) {
temp.Emit (ec);
temp.Release (ec);
temp = null;
}
}
public override void Emit (EmitContext ec)
{
Emit (ec, false);
}
public override void EmitSideEffect (EmitContext ec)
{
bool is_volatile = (spec.Modifiers & Modifiers.VOLATILE) != 0;
if (is_volatile || is_marshal_by_ref ())
base.EmitSideEffect (ec);
}
public override void Error_VariableIsUsedBeforeItIsDeclared (Report r, string name)
{
r.Error (844, loc,
"A local variable `{0}' cannot be used before it is declared. Consider renaming the local variable when it hides the field `{1}'",
name, GetSignatureForError ());
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
if ((mode & AddressOp.Store) != 0)
spec.MemberDefinition.SetIsAssigned ();
if ((mode & AddressOp.Load) != 0)
spec.MemberDefinition.SetIsUsed ();
//
// Handle initonly fields specially: make a copy and then
// get the address of the copy.
//
bool need_copy;
if (spec.IsReadOnly){
need_copy = true;
if (ec.HasSet (EmitContext.Options.ConstructorScope)){
if (IsStatic){
if (ec.IsStatic)
need_copy = false;
} else
need_copy = false;
}
} else
need_copy = false;
if (need_copy){
LocalBuilder local;
Emit (ec);
local = ec.DeclareLocal (type, false);
ec.Emit (OpCodes.Stloc, local);
ec.Emit (OpCodes.Ldloca, local);
return;
}
if (IsStatic){
ec.Emit (OpCodes.Ldsflda, spec);
} else {
if (!prepared)
EmitInstance (ec, false);
ec.Emit (OpCodes.Ldflda, spec);
}
}
public SLE.Expression MakeAssignExpression (BuilderContext ctx)
{
return MakeExpression (ctx);
}
public override SLE.Expression MakeExpression (BuilderContext ctx)
{
return SLE.Expression.Field (InstanceExpression.MakeExpression (ctx), spec.GetMetaInfo ());
}
}
///
/// Expression that evaluates to a Property. The Assign class
/// might set the `Value' expression if we are in an assignment.
///
/// This is not an LValue because we need to re-write the expression, we
/// can not take data from the stack and store it.
///
public class PropertyExpr : MemberExpr, IDynamicAssign
{
PropertySpec spec;
// getter and setter can be different for base calls
MethodSpec getter, setter;
TypeArguments targs;
LocalTemporary temp;
bool prepared;
public PropertyExpr (PropertySpec spec, Location l)
{
this.spec = spec;
loc = l;
type = spec.MemberType;
}
#region Properties
public override string Name {
get {
return spec.Name;
}
}
public override bool IsInstance {
get {
return !IsStatic;
}
}
public override bool IsStatic {
get {
return spec.IsStatic;
}
}
public PropertySpec PropertyInfo {
get {
return spec;
}
}
#endregion
public override Expression CreateExpressionTree (ResolveContext ec)
{
Arguments args;
if (IsSingleDimensionalArrayLength ()) {
args = new Arguments (1);
args.Add (new Argument (InstanceExpression.CreateExpressionTree (ec)));
return CreateExpressionFactoryCall (ec, "ArrayLength", args);
}
args = new Arguments (2);
if (InstanceExpression == null)
args.Add (new Argument (new NullLiteral (loc)));
else
args.Add (new Argument (InstanceExpression.CreateExpressionTree (ec)));
args.Add (new Argument (new TypeOfMethod (getter, loc)));
return CreateExpressionFactoryCall (ec, "Property", args);
}
public Expression CreateSetterTypeOfExpression ()
{
return new TypeOfMethod (setter, loc);
}
public override TypeSpec DeclaringType {
get {
return spec.DeclaringType;
}
}
public override string GetSignatureForError ()
{
return TypeManager.GetFullNameSignature (spec);
}
public SLE.Expression MakeAssignExpression (BuilderContext ctx)
{
return SLE.Expression.Property (InstanceExpression.MakeExpression (ctx), (MethodInfo) setter.GetMetaInfo ());
}
public override SLE.Expression MakeExpression (BuilderContext ctx)
{
return SLE.Expression.Property (InstanceExpression.MakeExpression (ctx), (MethodInfo) getter.GetMetaInfo ());
}
bool InstanceResolve (ResolveContext ec, bool lvalue_instance, bool must_do_cs1540_check)
{
if (!ResolveInstanceExpression (ec))
return true;
InstanceExpression = InstanceExpression.Resolve (ec);
if (lvalue_instance && InstanceExpression != null)
InstanceExpression = InstanceExpression.ResolveLValue (ec, EmptyExpression.LValueMemberAccess);
if (InstanceExpression == null)
return false;
InstanceExpression.CheckMarshalByRefAccess (ec);
if (must_do_cs1540_check && (InstanceExpression != EmptyExpression.Null) &&
!(InstanceExpression is BaseThis) &&
!TypeManager.IsInstantiationOfSameGenericType (InstanceExpression.Type, ec.CurrentType) &&
!TypeManager.IsNestedChildOf (ec.CurrentType, InstanceExpression.Type) &&
!TypeManager.IsSubclassOf (InstanceExpression.Type, ec.CurrentType)) {
ec.Report.SymbolRelatedToPreviousError (spec);
Error_CannotAccessProtected (ec, loc, spec, InstanceExpression.Type, ec.CurrentType);
return false;
}
return true;
}
void Error_PropertyNotValid (ResolveContext ec)
{
ec.Report.SymbolRelatedToPreviousError (spec);
ec.Report.Error (1546, loc, "Property or event `{0}' is not supported by the C# language",
GetSignatureForError ());
}
public bool IsAccessibleFrom (TypeSpec invocation_type, bool lvalue)
{
bool dummy;
var accessor = lvalue ? spec.Set : spec.Get;
if (accessor == null && lvalue)
accessor = spec.Get;
return accessor != null && IsMemberAccessible (invocation_type, accessor, out dummy);
}
bool IsSingleDimensionalArrayLength ()
{
if (DeclaringType != TypeManager.array_type || !spec.HasGet || Name != "Length")
return false;
ArrayContainer ac = InstanceExpression.Type as ArrayContainer;
return ac != null && ac.Rank == 1;
}
protected override Expression DoResolve (ResolveContext ec)
{
eclass = ExprClass.PropertyAccess;
bool must_do_cs1540_check = false;
ec.Report.DisableReporting ();
bool res = ResolveGetter (ec, ref must_do_cs1540_check);
ec.Report.EnableReporting ();
if (!res) {
if (InstanceExpression != null) {
TypeSpec expr_type = InstanceExpression.Type;
ExtensionMethodGroupExpr ex_method_lookup = ec.LookupExtensionMethod (expr_type, Name, 0, loc);
if (ex_method_lookup != null) {
ex_method_lookup.ExtensionExpression = InstanceExpression;
ex_method_lookup.SetTypeArguments (ec, targs);
return ex_method_lookup.Resolve (ec);
}
}
ResolveGetter (ec, ref must_do_cs1540_check);
return null;
}
if (!InstanceResolve (ec, false, must_do_cs1540_check))
return null;
if (type.IsPointer && !ec.IsUnsafe) {
UnsafeError (ec, loc);
}
getter = CandidateToBaseOverride (ec, spec.Get);
//
// Only base will allow this invocation to happen.
//
if (IsBase && getter.IsAbstract) {
Error_CannotCallAbstractBase (ec, spec.GetSignatureForError ());
}
if (!ec.IsObsolete) {
ObsoleteAttribute oa = spec.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, GetSignatureForError (), loc, ec.Report);
}
return this;
}
override public Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
eclass = ExprClass.PropertyAccess;
if (right_side == EmptyExpression.OutAccess.Instance) {
if (ec.CurrentBlock.Toplevel.GetParameterReference (spec.Name, loc) is MemberAccess) {
ec.Report.Error (1939, loc, "A range variable `{0}' may not be passes as `ref' or `out' parameter",
spec.Name);
} else {
right_side.DoResolveLValue (ec, this);
}
return null;
}
if (right_side == EmptyExpression.LValueMemberAccess || right_side == EmptyExpression.LValueMemberOutAccess) {
Error_CannotModifyIntermediateExpressionValue (ec);
}
if (spec.IsNotRealProperty) {
Error_PropertyNotValid (ec);
return null;
}
if (!spec.HasSet){
if (ec.CurrentBlock.Toplevel.GetParameterReference (spec.Name, loc) is MemberAccess) {
ec.Report.Error (1947, loc, "A range variable `{0}' cannot be assigned to. Consider using `let' clause to store the value",
spec.Name);
} else {
ec.Report.Error (200, loc, "Property or indexer `{0}' cannot be assigned to (it is read only)",
GetSignatureForError ());
}
return null;
}
if (targs != null) {
base.SetTypeArguments (ec, targs);
return null;
}
bool must_do_cs1540_check;
if (!IsMemberAccessible (ec.CurrentType, spec.Set, out must_do_cs1540_check)) {
if (spec.HasDifferentAccessibility) {
ec.Report.SymbolRelatedToPreviousError (spec.Set);
ec.Report.Error (272, loc, "The property or indexer `{0}' cannot be used in this context because the set accessor is inaccessible",
TypeManager.CSharpSignature (spec));
} else {
ec.Report.SymbolRelatedToPreviousError (spec.Set);
ErrorIsInaccesible (loc, TypeManager.CSharpSignature (spec.Set), ec.Report);
}
return null;
}
if (!InstanceResolve (ec, TypeManager.IsStruct (spec.DeclaringType), must_do_cs1540_check))
return null;
setter = CandidateToBaseOverride (ec, spec.Set);
//
// Only base will allow this invocation to happen.
//
if (IsBase && setter.IsAbstract){
Error_CannotCallAbstractBase (ec, setter.GetSignatureForError ());
}
if (spec.MemberType.IsPointer && !ec.IsUnsafe) {
UnsafeError (ec, loc);
}
if (!ec.IsObsolete) {
ObsoleteAttribute oa = spec.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, GetSignatureForError (), loc, ec.Report);
}
return this;
}
public override void Emit (EmitContext ec)
{
Emit (ec, false);
}
public void Emit (EmitContext ec, bool leave_copy)
{
//
// Special case: length of single dimension array property is turned into ldlen
//
if (IsSingleDimensionalArrayLength ()) {
if (!prepared)
EmitInstance (ec, false);
ec.Emit (OpCodes.Ldlen);
ec.Emit (OpCodes.Conv_I4);
return;
}
Invocation.EmitCall (ec, InstanceExpression, getter, null, loc, prepared, false);
if (leave_copy) {
ec.Emit (OpCodes.Dup);
if (!IsStatic) {
temp = new LocalTemporary (this.Type);
temp.Store (ec);
}
}
}
//
// Implements the IAssignMethod interface for assignments
//
public void EmitAssign (EmitContext ec, Expression source, bool leave_copy, bool prepare_for_load)
{
Expression my_source = source;
if (prepare_for_load) {
prepared = true;
source.Emit (ec);
if (leave_copy) {
ec.Emit (OpCodes.Dup);
if (!IsStatic) {
temp = new LocalTemporary (this.Type);
temp.Store (ec);
}
}
} else if (leave_copy) {
source.Emit (ec);
temp = new LocalTemporary (this.Type);
temp.Store (ec);
my_source = temp;
}
Arguments args = new Arguments (1);
args.Add (new Argument (my_source));
Invocation.EmitCall (ec, InstanceExpression, setter, args, loc, false, prepared);
if (temp != null) {
temp.Emit (ec);
temp.Release (ec);
}
}
bool ResolveGetter (ResolveContext ec, ref bool must_do_cs1540_check)
{
if (targs != null) {
base.SetTypeArguments (ec, targs);
return false;
}
if (spec.IsNotRealProperty) {
Error_PropertyNotValid (ec);
return false;
}
if (!spec.HasGet) {
if (InstanceExpression != EmptyExpression.Null) {
ec.Report.SymbolRelatedToPreviousError (spec);
ec.Report.Error (154, loc, "The property or indexer `{0}' cannot be used in this context because it lacks the `get' accessor",
spec.GetSignatureForError ());
return false;
}
}
if (spec.HasGet && !IsMemberAccessible (ec.CurrentType, spec.Get, out must_do_cs1540_check)) {
if (spec.HasDifferentAccessibility) {
ec.Report.SymbolRelatedToPreviousError (spec.Get);
ec.Report.Error (271, loc, "The property or indexer `{0}' cannot be used in this context because the get accessor is inaccessible",
TypeManager.CSharpSignature (spec));
} else {
ec.Report.SymbolRelatedToPreviousError (spec.Get);
ErrorIsInaccesible (loc, TypeManager.CSharpSignature (spec.Get), ec.Report);
}
return false;
}
return true;
}
public override void SetTypeArguments (ResolveContext ec, TypeArguments ta)
{
targs = ta;
}
}
///
/// Fully resolved expression that evaluates to an Event
///
public class EventExpr : MemberExpr
{
readonly EventSpec spec;
public EventExpr (EventSpec spec, Location loc)
{
this.spec = spec;
this.loc = loc;
}
public override string Name {
get {
return spec.Name;
}
}
public override bool IsInstance {
get {
return !spec.IsStatic;
}
}
public override bool IsStatic {
get {
return spec.IsStatic;
}
}
public override TypeSpec DeclaringType {
get {
return spec.DeclaringType;
}
}
public void Error_AssignmentEventOnly (ResolveContext ec)
{
ec.Report.Error (79, loc, "The event `{0}' can only appear on the left hand side of `+=' or `-=' operator",
GetSignatureForError ());
}
public override MemberExpr ResolveMemberAccess (ResolveContext ec, Expression left, SimpleName original)
{
//
// If the event is local to this class, we transform ourselves into a FieldExpr
//
if (spec.DeclaringType == ec.CurrentType ||
TypeManager.IsNestedChildOf(ec.CurrentType, spec.DeclaringType)) {
// TODO: Breaks dynamic binder as currect context fields are imported and not compiled
// EventField mi = spec.MemberDefinition as EventField;
if (spec.BackingField != null) {
spec.MemberDefinition.SetIsUsed ();
if (!ec.IsObsolete) {
ObsoleteAttribute oa = spec.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, spec.GetSignatureForError (), loc, ec.Report);
}
if ((spec.Modifiers & (Modifiers.ABSTRACT | Modifiers.EXTERN)) != 0 && !ec.HasSet (ResolveContext.Options.CompoundAssignmentScope))
Error_AssignmentEventOnly (ec);
FieldExpr ml = new FieldExpr (spec.BackingField, loc);
InstanceExpression = null;
return ml.ResolveMemberAccess (ec, left, original);
}
}
if (!ec.HasSet (ResolveContext.Options.CompoundAssignmentScope))
Error_AssignmentEventOnly (ec);
return base.ResolveMemberAccess (ec, left, original);
}
bool InstanceResolve (ResolveContext ec, bool must_do_cs1540_check)
{
if (IsBase && spec.IsAbstract) {
Error_CannotCallAbstractBase (ec, spec.GetSignatureForError ());
}
if (!ResolveInstanceExpression (ec))
return true;
InstanceExpression.Resolve (ec);
//
// This is using the same mechanism as the CS1540 check in PropertyExpr.
// However, in the Event case, we reported a CS0122 instead.
//
// TODO: Exact copy from PropertyExpr
//
if (must_do_cs1540_check && InstanceExpression != EmptyExpression.Null &&
!TypeManager.IsInstantiationOfSameGenericType (InstanceExpression.Type, ec.CurrentType) &&
!TypeManager.IsNestedChildOf (ec.CurrentType, InstanceExpression.Type) &&
!TypeManager.IsSubclassOf (InstanceExpression.Type, ec.CurrentType)) {
ec.Report.SymbolRelatedToPreviousError (spec);
ErrorIsInaccesible (loc, TypeManager.CSharpSignature (spec), ec.Report);
return false;
}
return true;
}
public bool IsAccessibleFrom (TypeSpec invocation_type)
{
bool dummy;
return IsMemberAccessible (invocation_type, spec.AccessorAdd, out dummy) &&
IsMemberAccessible (invocation_type, spec.AccessorRemove, out dummy);
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
throw new NotSupportedException ("ET");
}
public override Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
// contexts where an LValue is valid have already devolved to FieldExprs
Error_CannotAssign (ec);
return null;
}
protected override Expression DoResolve (ResolveContext ec)
{
eclass = ExprClass.EventAccess;
bool must_do_cs1540_check;
if (!(IsMemberAccessible (ec.CurrentType, spec.AccessorAdd, out must_do_cs1540_check) &&
IsMemberAccessible (ec.CurrentType, spec.AccessorRemove, out must_do_cs1540_check))) {
ec.Report.SymbolRelatedToPreviousError (spec);
ErrorIsInaccesible (loc, TypeManager.CSharpSignature (spec), ec.Report);
return null;
}
type = spec.MemberType;
if (!InstanceResolve (ec, must_do_cs1540_check))
return null;
if (!ec.HasSet (ResolveContext.Options.CompoundAssignmentScope)) {
Error_CannotAssign (ec);
return null;
}
if (!ec.IsObsolete) {
var oa = spec.GetAttributeObsolete ();
if (oa != null)
AttributeTester.Report_ObsoleteMessage (oa, GetSignatureForError (), loc, ec.Report);
}
spec.MemberDefinition.SetIsUsed ();
return this;
}
public override void Emit (EmitContext ec)
{
throw new NotSupportedException ();
//Error_CannotAssign ();
}
public void Error_CannotAssign (ResolveContext ec)
{
ec.Report.Error (70, loc,
"The event `{0}' can only appear on the left hand side of += or -= when used outside of the type `{1}'",
GetSignatureForError (), TypeManager.CSharpName (spec.DeclaringType));
}
public override string GetSignatureForError ()
{
return TypeManager.CSharpSignature (spec);
}
public void EmitAddOrRemove (EmitContext ec, bool is_add, Expression source)
{
Arguments args = new Arguments (1);
args.Add (new Argument (source));
Invocation.EmitCall (ec, InstanceExpression, is_add ? spec.AccessorAdd : spec.AccessorRemove, args, loc);
}
}
public class TemporaryVariable : VariableReference
{
LocalInfo li;
public TemporaryVariable (TypeSpec type, Location loc)
{
this.type = type;
this.loc = loc;
}
public override Expression CreateExpressionTree (ResolveContext ec)
{
throw new NotSupportedException ("ET");
}
protected override Expression DoResolve (ResolveContext ec)
{
eclass = ExprClass.Variable;
TypeExpr te = new TypeExpression (type, loc);
li = ec.CurrentBlock.AddTemporaryVariable (te, loc);
if (!li.Resolve (ec))
return null;
//
// Don't capture temporary variables except when using
// iterator redirection
//
if (ec.CurrentAnonymousMethod != null && ec.CurrentAnonymousMethod.IsIterator && ec.IsVariableCapturingRequired) {
AnonymousMethodStorey storey = li.Block.Explicit.CreateAnonymousMethodStorey (ec);
storey.CaptureLocalVariable (ec, li);
}
return this;
}
public override Expression DoResolveLValue (ResolveContext ec, Expression right_side)
{
return Resolve (ec);
}
public override void Emit (EmitContext ec)
{
Emit (ec, false);
}
public void EmitAssign (EmitContext ec, Expression source)
{
EmitAssign (ec, source, false, false);
}
public override HoistedVariable GetHoistedVariable (AnonymousExpression ae)
{
return li.HoistedVariant;
}
public override bool IsFixed {
get { return true; }
}
public override bool IsRef {
get { return false; }
}
public override string Name {
get { throw new NotImplementedException (); }
}
public override void SetHasAddressTaken ()
{
throw new NotImplementedException ();
}
protected override ILocalVariable Variable {
get { return li; }
}
public override VariableInfo VariableInfo {
get { throw new NotImplementedException (); }
}
}
///
/// Handles `var' contextual keyword; var becomes a keyword only
/// if no type called var exists in a variable scope
///
class VarExpr : SimpleName
{
// Used for error reporting only
int initializers_count;
public VarExpr (Location loc)
: base ("var", loc)
{
initializers_count = 1;
}
public int VariableInitializersCount {
set {
this.initializers_count = value;
}
}
public bool InferType (ResolveContext ec, Expression right_side)
{
if (type != null)
throw new InternalErrorException ("An implicitly typed local variable could not be redefined");
type = right_side.Type;
if (type == TypeManager.null_type || type == TypeManager.void_type || type == InternalType.AnonymousMethod || type == InternalType.MethodGroup) {
ec.Report.Error (815, loc, "An implicitly typed local variable declaration cannot be initialized with `{0}'",
right_side.GetSignatureForError ());
return false;
}
eclass = ExprClass.Variable;
return true;
}
protected override void Error_TypeOrNamespaceNotFound (IMemberContext ec)
{
if (RootContext.Version < LanguageVersion.V_3)
base.Error_TypeOrNamespaceNotFound (ec);
else
ec.Compiler.Report.Error (825, loc, "The contextual keyword `var' may only appear within a local variable declaration");
}
public override TypeExpr ResolveAsContextualType (IMemberContext rc, bool silent)
{
TypeExpr te = base.ResolveAsContextualType (rc, true);
if (te != null)
return te;
if (RootContext.Version < LanguageVersion.V_3)
rc.Compiler.Report.FeatureIsNotAvailable (loc, "implicitly typed local variable");
if (initializers_count == 1)
return null;
if (initializers_count > 1) {
rc.Compiler.Report.Error (819, loc, "An implicitly typed local variable declaration cannot include multiple declarators");
initializers_count = 1;
return null;
}
if (initializers_count == 0) {
initializers_count = 1;
rc.Compiler.Report.Error (818, loc, "An implicitly typed local variable declarator must include an initializer");
return null;
}
return null;
}
}
}