Beispiel #1
0
        public ISymbolValue Visit(TemplateInstanceExpression tix)
        {
            var ImplicitlyExecute = this.ImplicitlyExecute;

            this.ImplicitlyExecute = true;

            return(TryDoCTFEOrGetValueRefs(AmbiguousType.Get(ExpressionTypeEvaluation.GetOverloads(tix, ctxt), tix), tix, ImplicitlyExecute));
        }
        public AbstractType TryGetDType(IDBacktraceSymbol s)
        {
            if (!s.HasParent)
            {
                TryUpdateStackFrameInfo();

                if (ctxt == null)
                {
                    return(null);
                }

                return(AmbiguousType.Get(ExpressionTypeEvaluation.GetOverloads(new IdentifierExpression(s.Name), ctxt, null)));
            }

            return(null);
        }
        public AbstractType Visit(PostfixExpression_Slice x)
        {
            var foreExpression = EvalForeExpression(x);

            // myArray[0]; myArray[0..5];
            if (foreExpression is MemberSymbol)
            {
                foreExpression = DResolver.StripMemberSymbols(foreExpression);
            }

            var udt = foreExpression as UserDefinedType;

            if (udt == null)
            {
                return(foreExpression);
            }

            AbstractType[] sliceArgs;
            if (x.FromExpression == null && x.ToExpression == null)
            {
                sliceArgs = null;
            }
            else
            {
                sliceArgs = new AbstractType[2];
                if (x.FromExpression != null)
                {
                    sliceArgs[0] = x.FromExpression.Accept(this);
                }
                if (x.ToExpression != null)
                {
                    sliceArgs[1] = x.ToExpression.Accept(this);
                }
            }

            ctxt.CurrentContext.IntroduceTemplateParameterTypes(udt);

            var overloads = TypeDeclarationResolver.ResolveFurtherTypeIdentifier(OpSliceIdHash, AmbiguousType.TryDissolve(foreExpression), ctxt, x, false);

            overloads = TemplateInstanceHandler.DeduceParamsAndFilterOverloads(overloads, sliceArgs, true, ctxt);

            ctxt.CurrentContext.RemoveParamTypesFromPreferredLocals(udt);
            return(TryPretendMethodExecution(AmbiguousType.Get(overloads, x), x, sliceArgs) ?? foreExpression);
        }
        /// <summary>
        /// Returns either all unfiltered and undeduced overloads of a member of a base type/value (like b from type a if the expression is a.b).
        /// if <param name="EvalAndFilterOverloads"></param> is false.
        /// If true, all overloads will be deduced, filtered and evaluated, so that (in most cases,) a one-item large array gets returned
        /// which stores the return value of the property function b that is executed without arguments.
        /// Also handles UFCS - so if filtering is wanted, the function becom
        /// </summary>
        public static R[] EvalPostfixAccessExpression <R>(ExpressionVisitor <R> vis, ResolutionContext ctxt, PostfixExpression_Access acc,
                                                          ISemantic resultBase = null, bool EvalAndFilterOverloads = true, bool ResolveImmediateBaseType = true, AbstractSymbolValueProvider ValueProvider = null)
            where R : class, ISemantic
        {
            if (acc == null)
            {
                return(null);
            }

            var baseExpression = resultBase ?? (acc.PostfixForeExpression != null ? acc.PostfixForeExpression.Accept(vis) as ISemantic : null);

            if (acc.AccessExpression is NewExpression)
            {
                /*
                 * This can be both a normal new-Expression as well as an anonymous class declaration!
                 */
                //TODO!
                return(null);
            }


            AbstractType[] overloads;
            var            optBackup = ctxt.CurrentContext.ContextDependentOptions;

            if (acc.AccessExpression is TemplateInstanceExpression)
            {
                if (!ResolveImmediateBaseType)
                {
                    ctxt.CurrentContext.ContextDependentOptions |= ResolutionOptions.DontResolveBaseTypes;
                }

                var tix = (TemplateInstanceExpression)acc.AccessExpression;
                // Do not deduce and filter if superior expression is a method call since call arguments' types also count as template arguments!
                overloads = ExpressionTypeEvaluation.GetOverloads(tix, ctxt, new[] { AbstractType.Get(baseExpression) }, EvalAndFilterOverloads);

                if (!ResolveImmediateBaseType)
                {
                    ctxt.CurrentContext.ContextDependentOptions = optBackup;
                }
            }

            else if (acc.AccessExpression is IdentifierExpression)
            {
                var id = acc.AccessExpression as IdentifierExpression;

                if (ValueProvider != null && EvalAndFilterOverloads && baseExpression != null)
                {
                    var staticPropResult = StaticProperties.TryEvalPropertyValue(ValueProvider, baseExpression, id.ValueStringHash);
                    if (staticPropResult != null)
                    {
                        return new[] { (R)staticPropResult }
                    }
                    ;
                }

                if (!ResolveImmediateBaseType)
                {
                    ctxt.CurrentContext.ContextDependentOptions |= ResolutionOptions.DontResolveBaseTypes;
                }

                overloads = ExpressionTypeEvaluation.GetOverloads(id, ctxt, AmbiguousType.TryDissolve(AbstractType.Get(baseExpression)), EvalAndFilterOverloads);

                if (!ResolveImmediateBaseType)
                {
                    ctxt.CurrentContext.ContextDependentOptions = optBackup;
                }
            }
            else
            {            /*
                          *     if (eval){
                          *             EvalError(acc, "Invalid access expression");
                          *             return null;
                          *     }*/
                ctxt.LogError(acc, "Invalid post-dot expression");
                return(null);
            }

            // If evaluation active and the access expression is stand-alone, return a single item only.
            if (EvalAndFilterOverloads && ValueProvider != null)
            {
                return new[] { (R) new Evaluation(ValueProvider).TryDoCTFEOrGetValueRefs(AmbiguousType.Get(overloads, acc.AccessExpression), acc.AccessExpression) }
            }
            ;

            return(overloads as R[]);
        }

        ISymbolValue EvalForeExpression(PostfixExpression ex)
        {
            return(ex.PostfixForeExpression != null?ex.PostfixForeExpression.Accept(this) : null);
        }
        public static AbstractType EvalMethodCall(AbstractType[] baseExpression, ISymbolValue baseValue, TemplateInstanceExpression tix,
                                                  ResolutionContext ctxt,
                                                  PostfixExpression_MethodCall call, out List <ISemantic> callArguments, out ISymbolValue delegateValue,
                                                  bool returnBaseTypeOnly, AbstractSymbolValueProvider ValueProvider = null)
        {
            //TODO: Refactor this crap!

            delegateValue = null;
            callArguments = null;

            var methodOverloads = new List <AbstractType>();

            #region Search possible methods, opCalls or delegates that could be called
            bool requireStaticItems = true;             //TODO: What if there's an opCall and a foreign method at the same time? - and then this variable would be bullshit
            IEnumerable <AbstractType> scanResults = baseExpression;
            var nextResults = new List <AbstractType>();

            while (scanResults != null)
            {
                foreach (var b in scanResults)
                {
                    if (b is AmbiguousType)
                    {
                        nextResults.AddRange((b as AmbiguousType).Overloads);
                    }
                    else if (b is TemplateParameterSymbol)
                    {
                        nextResults.Add((b as TemplateParameterSymbol).Base);
                    }
                    else if (b is MemberSymbol)
                    {
                        var mr = (MemberSymbol)b;

                        if (mr.Definition is DMethod)
                        {
                            methodOverloads.Add(mr);
                            continue;
                        }
                        else if (mr.Definition is DVariable)
                        {
                            // If we've got a variable here, get its base type/value reference
                            if (ValueProvider != null)
                            {
                                var dgVal = ValueProvider[(DVariable)mr.Definition] as DelegateValue;

                                if (dgVal != null)
                                {
                                    nextResults.Add(dgVal.Definition);
                                    continue;
                                }
                                else
                                {
                                    ValueProvider.LogError(call, "Variable must be a delegate, not anything else");
                                    return(null);
                                }
                            }
                            else
                            {
                                var bt = mr.Base ?? TypeDeclarationResolver.ResolveSingle(mr.Definition.Type, ctxt);

                                // Must be of type delegate
                                if (bt is DelegateType)
                                {
                                    var ret = HandleCallDelegateType(ValueProvider, bt as DelegateType, methodOverloads, returnBaseTypeOnly);
                                    if (ret is ISymbolValue)
                                    {
                                        delegateValue = ret as ISymbolValue;
                                        return(null);
                                    }
                                    else if (ret is AbstractType)
                                    {
                                        return(ret as AbstractType);
                                    }
                                }
                                else
                                {
                                    /*
                                     * If mr.Node is not a method, so e.g. if it's a variable
                                     * pointing to a delegate
                                     *
                                     * class Foo
                                     * {
                                     *	string opCall() {  return "asdf";  }
                                     * }
                                     *
                                     * Foo f=new Foo();
                                     * f(); -- calls opCall, opCall is not static
                                     */
                                    nextResults.Add(bt);
                                    requireStaticItems = false;
                                }
                                //TODO: Can other types work as function/are callable?
                            }
                        }
                    }
                    else if (b is DelegateType)
                    {
                        var ret = HandleCallDelegateType(ValueProvider, b as DelegateType, methodOverloads, returnBaseTypeOnly);
                        if (ret is ISymbolValue)
                        {
                            delegateValue = ret as ISymbolValue;
                            return(null);
                        }
                        else if (ret is AbstractType)
                        {
                            return(ret as AbstractType);
                        }
                    }
                    else if (b is ClassType || b is StructType)
                    {
                        var tit = (TemplateIntermediateType)b;

                        /*
                         * auto a = MyStruct(); -- opCall-Overloads can be used
                         */
                        var classDef = tit.Definition;

                        if (classDef == null)
                        {
                            continue;
                        }

                        foreach (var i in ExpressionTypeEvaluation.GetOpCalls(tit, requireStaticItems))
                        {
                            methodOverloads.Add(TypeDeclarationResolver.HandleNodeMatch(i, ctxt, b, call) as MemberSymbol);
                        }

                        /*
                         * Every struct can contain a default ctor:
                         *
                         * struct S { int a; bool b; }
                         *
                         * auto s = S(1,true); -- ok
                         * auto s2= new S(2,false); -- error, no constructor found!
                         */
                        if (b is StructType && methodOverloads.Count == 0)
                        {
                            //TODO: Deduce parameters
                            return(b);
                        }
                    }

                    /*
                     * If the overload is a template, it quite exclusively means that we'll handle a method that is the only
                     * child inside a template + that is named as the template.
                     */
                    else if (b is TemplateType)
                    {
                        methodOverloads.Add(b);
                    }
                    else if (b is PrimitiveType)                     // dmd 2.066: Uniform Construction Syntax. creal(3) is of type creal.
                    {
                        methodOverloads.Add(b);
                    }
                }

                scanResults = nextResults.Count == 0 ? null : nextResults.ToArray();
                nextResults.Clear();
            }
            #endregion

            if (methodOverloads.Count == 0)
            {
                return(null);
            }

            // Get all arguments' types
            callArguments = new List <ISemantic>();

            if (call.Arguments != null)
            {
                if (ValueProvider != null)
                {
                    foreach (var arg in call.Arguments)
                    {
                        callArguments.Add(arg != null ? Evaluation.EvaluateValue(arg, ValueProvider) : null);
                    }
                }
                else
                {
                    foreach (var arg in call.Arguments)
                    {
                        callArguments.Add(arg != null ? ExpressionTypeEvaluation.EvaluateType(arg, ctxt) : null);
                    }
                }
            }

            #region If explicit template type args were given, try to associate them with each overload
            if (tix != null)
            {
                var args             = TemplateInstanceHandler.PreResolveTemplateArgs(tix, ctxt);
                var deducedOverloads = TemplateInstanceHandler.DeduceParamsAndFilterOverloads(methodOverloads, args, true, ctxt);
                methodOverloads.Clear();
                if (deducedOverloads != null)
                {
                    methodOverloads.AddRange(deducedOverloads);
                }
            }
            #endregion

            #region Filter by parameter-argument comparison
            var          argTypeFilteredOverloads   = new List <AbstractType>();
            bool         hasHandledUfcsResultBefore = false;
            AbstractType untemplatedMethodResult    = null;

            foreach (var ov in methodOverloads)
            {
                if (ov is MemberSymbol)
                {
                    HandleDMethodOverload(ctxt, ValueProvider != null, baseValue, callArguments, returnBaseTypeOnly, argTypeFilteredOverloads, ref hasHandledUfcsResultBefore,
                                          ov as MemberSymbol, ref untemplatedMethodResult);
                }
                else if (ov is DelegateType)
                {
                    var dg = ov as DelegateType;
                    var bt = dg.Base ?? TypeDeclarationResolver.GetMethodReturnType(dg, ctxt);

                    //TODO: Param-Arg check

                    if (returnBaseTypeOnly)
                    {
                        argTypeFilteredOverloads.Add(bt);
                    }
                    else
                    {
                        if (dg.Base == null)
                        {
                            if (dg.IsFunctionLiteral)
                            {
                                dg = new DelegateType(bt, dg.DeclarationOrExpressionBase as FunctionLiteral, dg.Parameters);
                            }
                            else
                            {
                                dg = new DelegateType(bt, dg.DeclarationOrExpressionBase as DelegateDeclaration, dg.Parameters);
                            }
                        }
                        argTypeFilteredOverloads.Add(new DelegateCallSymbol(dg, call));
                    }
                }
                else if (ov is PrimitiveType)                 // dmd 2.066: Uniform Construction Syntax. creal(3) is of type creal.
                {
                    if (ValueProvider != null)
                    {
                        if (callArguments == null || callArguments.Count != 1)
                        {
                            ValueProvider.LogError(call, "Uniform construction syntax expects exactly one argument");
                        }
                        else
                        {
                            var pv = callArguments[0] as PrimitiveValue;
                            if (pv == null)
                            {
                                ValueProvider.LogError(call, "Uniform construction syntax expects one built-in scalar value as first argument");
                            }
                            else
                            {
                                delegateValue = new PrimitiveValue(pv.Value, ov as PrimitiveType, pv.ImaginaryPart);
                            }
                        }
                    }

                    argTypeFilteredOverloads.Add(ov);
                }
            }

            // Prefer untemplated methods over templated ones
            if (untemplatedMethodResult != null)
            {
                return(untemplatedMethodResult);
            }
            #endregion

            return(AmbiguousType.Get(argTypeFilteredOverloads, tix));
        }
        public AbstractType Visit(IdentifierExpression id)
        {
            if (id.IsIdentifier)
            {
                return(TryPretendMethodExecution(AmbiguousType.Get(GetOverloads(id, ctxt), id)));
            }

            byte tt;

            switch (id.Format)
            {
            case Parser.LiteralFormat.CharLiteral:
                var tk = id.Subformat == LiteralSubformat.Utf32 ? DTokens.Dchar :
                         id.Subformat == LiteralSubformat.Utf16 ? DTokens.Wchar :
                         DTokens.Char;

                return(new PrimitiveType(tk, 0, id)
                {
                    NonStaticAccess = true
                });

            case LiteralFormat.FloatingPoint | LiteralFormat.Scalar:
                var im = id.Subformat.HasFlag(LiteralSubformat.Imaginary);

                tt = im ? DTokens.Idouble : DTokens.Double;

                if (id.Subformat.HasFlag(LiteralSubformat.Float))
                {
                    tt = im ? DTokens.Ifloat : DTokens.Float;
                }
                else if (id.Subformat.HasFlag(LiteralSubformat.Real))
                {
                    tt = im ? DTokens.Ireal : DTokens.Real;
                }

                return(new PrimitiveType(tt, 0, id)
                {
                    NonStaticAccess = true
                });

            case LiteralFormat.Scalar:
                var unsigned = id.Subformat.HasFlag(LiteralSubformat.Unsigned);

                if (id.Subformat.HasFlag(LiteralSubformat.Long))
                {
                    tt = unsigned ? DTokens.Ulong : DTokens.Long;
                }
                else
                {
                    tt = unsigned ? DTokens.Uint : DTokens.Int;
                }

                return(new PrimitiveType(tt, 0, id)
                {
                    NonStaticAccess = true
                });

            case Parser.LiteralFormat.StringLiteral:
            case Parser.LiteralFormat.VerbatimStringLiteral:
                var str = GetStringType(id.Subformat);
                str.NonStaticAccess = true;
                return(str);

            default:
                return(null);
            }
        }
 public AbstractType Visit(TemplateInstanceExpression tix)
 {
     return(TryPretendMethodExecution(AmbiguousType.Get(GetOverloads(tix, ctxt), tix)));
 }
        public AbstractType Visit(PostfixExpression_Index x)
        {
            var foreExpression = EvalForeExpression(x);

            // myArray[0]; myArray[0..5];
            // opIndex/opSlice ?
            if (foreExpression is MemberSymbol)
            {
                foreExpression = DResolver.StripMemberSymbols(foreExpression);
            }

            var udt = foreExpression as UserDefinedType;

            if (udt != null)
            {
                ctxt.CurrentContext.IntroduceTemplateParameterTypes(udt);

                var overloads = TypeDeclarationResolver.ResolveFurtherTypeIdentifier(OpIndexIdHash, AmbiguousType.TryDissolve(foreExpression), ctxt, x, false);
                if (overloads != null && overloads.Length > 0)
                {
                    var indexArgs = x.Arguments != null ? new AbstractType[x.Arguments.Length] : null;
                    for (int i = 0; i < indexArgs.Length; i++)
                    {
                        if (x.Arguments[i] != null)
                        {
                            indexArgs[i] = x.Arguments[i].Accept(this);
                        }
                    }

                    overloads = TemplateInstanceHandler.DeduceParamsAndFilterOverloads(overloads, indexArgs, true, ctxt);
                    ctxt.CurrentContext.RemoveParamTypesFromPreferredLocals(udt);
                    return(TryPretendMethodExecution(AmbiguousType.Get(overloads, x), x, indexArgs));
                }
                ctxt.CurrentContext.RemoveParamTypesFromPreferredLocals(udt);

                if (foreExpression is TemplateIntermediateType)
                {                //TODO: Proper resolution of alias this declarations
                    var tit = foreExpression as TemplateIntermediateType;
                    var ch  = tit.Definition[DVariable.AliasThisIdentifierHash];
                    if (ch != null)
                    {
                        foreach (DVariable aliasThis in ch)
                        {
                            foreExpression = TypeDeclarationResolver.HandleNodeMatch(aliasThis, ctxt, foreExpression);
                            if (foreExpression != null)
                            {
                                break;                                 // HACK: Just omit other alias this' to have a quick run-through
                            }
                        }
                    }

                    if (foreExpression == null)
                    {
                        return(tit);
                    }
                }
            }

            foreExpression = DResolver.StripMemberSymbols(foreExpression);

            if (foreExpression is AssocArrayType)
            {
                var ar = foreExpression as AssocArrayType;

                /*
                 * myType_Array[0] -- returns TypeResult myType
                 * return the value type of a given array result
                 */
                //TODO: Handle opIndex overloads
                if (ar.ValueType != null)
                {
                    ar.ValueType.NonStaticAccess = true;
                }

                return(new ArrayAccessSymbol(x, ar.ValueType));
            }

            /*
             * int* a = new int[10];
             *
             * a[0] = 12;
             */
            else if (foreExpression is PointerType)
            {
                var b = (foreExpression as PointerType).Base;
                if (b != null)
                {
                    b.NonStaticAccess = true;
                }
                return(b);
            }
            //return new ArrayAccessSymbol(x,((PointerType)foreExpression).Base);

            else if (foreExpression is DTuple)
            {
                var tt = foreExpression as DTuple;

                if (x.Arguments != null && x.Arguments.Length != 0)
                {
                    var idx = Evaluation.EvaluateValue(x.Arguments[0], ctxt) as PrimitiveValue;

                    if (tt.Items == null)
                    {
                        ctxt.LogError(tt.DeclarationOrExpressionBase, "No items in Type tuple");
                    }
                    else if (idx == null || !DTokens.IsBasicType_Integral(idx.BaseTypeToken))
                    {
                        ctxt.LogError(x.Arguments[0], "Index expression must evaluate to integer value");
                    }
                    else if (idx.Value > (decimal)Int32.MaxValue ||
                             (int)idx.Value >= tt.Items.Length || idx.Value < 0m)
                    {
                        ctxt.LogError(x.Arguments[0], "Index number must be a value between 0 and " + tt.Items.Length);
                    }
                    else
                    {
                        return(AbstractType.Get(tt.Items[(int)idx.Value]));
                    }
                }
            }

            ctxt.LogError(x, "No matching base type for indexing operation");
            return(null);
        }
 public AbstractType Visit(PostfixExpression_Access ex)
 {
     return(TryPretendMethodExecution(AmbiguousType.Get(Evaluation.EvalPostfixAccessExpression(this, ctxt, ex))));
 }
        public AbstractType Visit(NewExpression nex)
        {
            // http://www.d-programming-language.org/expression.html#NewExpression
            AbstractType[] possibleTypes;

            if (nex.Type is IdentifierDeclaration)
            {
                possibleTypes = TypeDeclarationResolver.Resolve((IdentifierDeclaration)nex.Type, ctxt, filterForTemplateArgs: false);
            }
            else
            {
                possibleTypes = TypeDeclarationResolver.Resolve(nex.Type, ctxt);
            }

            var ctors = new Dictionary <DMethod, TemplateIntermediateType>();

            if (possibleTypes == null)
            {
                return(null);
            }

            foreach (var t in possibleTypes)
            {
                var ct = t as TemplateIntermediateType;
                if (ct != null &&
                    !ct.Definition.ContainsAttribute(DTokens.Abstract))
                {
                    foreach (var ctor in GetConstructors(ct))
                    {
                        // Omit all ctors that won't return the adequate
                        if (ct.Modifier != 0)
                        {
                            if (!ctor.ContainsAttribute(ct.Modifier, DTokens.Pure))
                            {
                                continue;
                            }
                        }
                        else if (ctor.Attributes != null && ctor.Attributes.Count != 0)
                        {
                            bool skip = false;
                            foreach (var attr in ctor.Attributes)
                            {
                                var mod = attr as Modifier;
                                if (mod != null)
                                {
                                    switch (mod.Token)
                                    {
                                    case DTokens.Const:
                                    case DTokens.Immutable:
                                    case DTokens.Shared:
                                    case DTokens.Nothrow:                                             // ?
                                        // not DTokens.Pure due to some mystical reasons
                                        skip = true;
                                        break;
                                    }

                                    if (skip)
                                    {
                                        break;
                                    }
                                }
                            }
                            if (skip)
                            {
                                continue;
                            }
                        }
                        ctors.Add(ctor, ct);
                    }
                }
                else if (t is AssocArrayType)
                {
                    t.NonStaticAccess = true;
                    return(AmbiguousType.Get(possibleTypes));
                }
            }

            if (ctors.Count == 0)
            {
                return(new UnknownType(nex));
            }

            // HACK: Return the base types immediately
            if (TryReturnMethodReturnType)
            {
                var ret = ctors.First().Value;                 // AmbiguousType.Get(ctors.Values);
                if (ret != null)
                {
                    ret.NonStaticAccess = true;
                }
                return(ret);
            }

            MemberSymbol finalCtor = null;

            //TODO: Determine argument types and filter out ctor overloads.
            var kvFirst = ctors.First();

            finalCtor = new MemberSymbol(kvFirst.Key, kvFirst.Value, nex);



            if (finalCtor != null)
            {
                return(TryPretendMethodExecution(finalCtor, nex));
            }

            var resolvedCtors = new List <AbstractType>();

            foreach (var kv in ctors)
            {
                resolvedCtors.Add(new MemberSymbol(kv.Key, kv.Value, nex));
            }

            return(TryPretendMethodExecution(AmbiguousType.Get(resolvedCtors, nex), nex));
        }
Beispiel #11
0
        public static AbstractType ResolveTypeLoosely(IEditorData editor, out NodeResolutionAttempt resolutionAttempt, ResolutionContext ctxt = null)
        {
            var o = GetScopedCodeObject(editor);

            if (ctxt == null)
            {
                ctxt = ResolutionContext.Create(editor, false);
            }

            AbstractType          ret        = null;
            NodeResolutionAttempt resAttempt = NodeResolutionAttempt.Normal;

            CodeCompletion.DoTimeoutableCompletionTask(null, ctxt, () =>
            {
                ctxt.Push(editor);

                var optionBackup = ctxt.CurrentContext.ContextDependentOptions;
                ctxt.CurrentContext.ContextDependentOptions |= ResolutionOptions.ReturnMethodReferencesOnly | ResolutionOptions.DontResolveAliases;

                if (o is IExpression)
                {
                    ret = ExpressionTypeEvaluation.EvaluateType((IExpression)o, ctxt, false);
                }
                else if (o is ITypeDeclaration)
                {
                    ret = TypeDeclarationResolver.ResolveSingle((ITypeDeclaration)o, ctxt);
                }
                else if (o is INode)
                {
                    ret = TypeDeclarationResolver.HandleNodeMatch(o as INode, ctxt, null, o);
                }
                else
                {
                    ret = null;
                }

                if (ret == null)
                {
                    resAttempt = NodeResolutionAttempt.NoParameterOrTemplateDeduction;

                    if (o is PostfixExpression_MethodCall)
                    {
                        o = (o as PostfixExpression_MethodCall).PostfixForeExpression;
                    }

                    ctxt.CurrentContext.ContextDependentOptions |= ResolutionOptions.NoTemplateParameterDeduction | ResolutionOptions.DontResolveAliases;

                    if (o is IdentifierExpression)
                    {
                        ret = AmbiguousType.Get(ExpressionTypeEvaluation.GetOverloads(o as IdentifierExpression, ctxt, deduceParameters: false), o);
                    }
                    else if (o is ITypeDeclaration)
                    {
                        ret = TypeDeclarationResolver.ResolveSingle(o as ITypeDeclaration, ctxt);
                    }
                    else if (o is IExpression)
                    {
                        ret = ExpressionTypeEvaluation.EvaluateType(o as IExpression, ctxt, false);
                    }
                }

                if (ret == null)
                {
                    resAttempt    = NodeResolutionAttempt.RawSymbolLookup;
                    var overloads = TypeDeclarationResolver.HandleNodeMatches(LookupIdRawly(editor, o as ISyntaxRegion), ctxt, null, o);
                    ret           = AmbiguousType.Get(overloads, o);
                }

                ctxt.CurrentContext.ContextDependentOptions = optionBackup;
            });

            resolutionAttempt = resAttempt;

            if (ret != null)
            {
                ret.DeclarationOrExpressionBase = o;
            }

            return(ret);
        }