Exemple #1
0
        /// <summary>
        /// Adds an entry to the map and propagates the substitution through
        /// all other entries in the type map.
        /// </summary>
        internal void AddAndPropagate(TypeParameterSymbol key, TypeWithModifiers value)
        {
            // @MattWindsor91 (Concept-C# 2017)
            //
            // This is an attempt to make TypeUnification perform a proper
            // unification where no mapping is dependent on another mapping.
            //
            // This is important for using unification for concepts, but less
            // so elsewhere.

            Debug.Assert(!Mapping.ContainsKey(key), "should not map the same type twice");

            // CONSIDER: performance
            var tmp = new MutableTypeMap();

            tmp.Add(key, value);

            var ms = Mapping.AsImmutable();

            foreach (var m in ms)
            {
                Mapping[m.Key] = m.Value.SubstituteType(tmp);
            }

            Add(key, value);
        }
        /// <summary>
        /// Determine whether there is any substitution of type parameters that will
        /// make two types identical.
        /// </summary>
        /// <param name="t1">LHS</param>
        /// <param name="t2">RHS</param>
        /// <param name="substitution">
        /// Substitutions performed so far (or null for none).
        /// Keys are type parameters, values are types (possibly type parameters).
        /// Will be updated with new substitutions by the callee.
        /// Should be ignored when false is returned.
        /// </param>
        /// <returns>True if there exists a type map such that Map(LHS) == Map(RHS).</returns>
        /// <remarks>
        /// Derived from Dev10's BSYMMGR::UnifyTypes.
        /// Two types will not unify if they have different custom modifiers.
        /// </remarks>
        private static bool CanUnifyHelper(TypeWithModifiers t1, TypeWithModifiers t2, ref MutableTypeMap substitution)
        {
            if (t1 == t2)
            {
                return true;
            }
            else if ((object)t1.Type == null || (object)t2.Type == null)
            {
                // Can't both be null or they would have been equal
                return false;
            }

            if (substitution != null)
            {
                t1 = t1.SubstituteType(substitution);
                t2 = t2.SubstituteType(substitution);
            }

            // If one of the types is a type parameter, then the substitution could make them equal.
            if (t1 == t2)
            {
                return true;
            }

            // We can avoid a lot of redundant checks if we ensure that we only have to check
            // for type parameters on the LHS
            if (!t1.Type.IsTypeParameter() && t2.Type.IsTypeParameter())
            {
                TypeWithModifiers tmp = t1;
                t1 = t2;
                t2 = tmp;
            }

            // If t1 is not a type parameter, then neither is t2
            Debug.Assert(t1.Type.IsTypeParameter() || !t2.Type.IsTypeParameter());

            switch (t1.Type.Kind)
            {
                case SymbolKind.ArrayType:
                    {
                        if (t2.Type.TypeKind != t1.Type.TypeKind || !t2.CustomModifiers.SequenceEqual(t1.CustomModifiers))
                        {
                            return false;
                        }

                        ArrayTypeSymbol at1 = (ArrayTypeSymbol)t1.Type;
                        ArrayTypeSymbol at2 = (ArrayTypeSymbol)t2.Type;

                        if (!at1.HasSameShapeAs(at2))
                        {
                            return false;
                        }

                        return CanUnifyHelper(new TypeWithModifiers(at1.ElementType, at1.CustomModifiers), new TypeWithModifiers(at2.ElementType, at2.CustomModifiers), ref substitution);
                    }
                case SymbolKind.PointerType:
                    {
                        if (t2.Type.TypeKind != t1.Type.TypeKind || !t2.CustomModifiers.SequenceEqual(t1.CustomModifiers))
                        {
                            return false;
                        }

                        PointerTypeSymbol pt1 = (PointerTypeSymbol)t1.Type;
                        PointerTypeSymbol pt2 = (PointerTypeSymbol)t2.Type;

                        return CanUnifyHelper(new TypeWithModifiers(pt1.PointedAtType, pt1.CustomModifiers), new TypeWithModifiers(pt2.PointedAtType, pt2.CustomModifiers), ref substitution);
                    }
                case SymbolKind.NamedType:
                case SymbolKind.ErrorType:
                    {
                        if (t2.Type.TypeKind != t1.Type.TypeKind || !t2.CustomModifiers.SequenceEqual(t1.CustomModifiers))
                        {
                            return false;
                        }

                        NamedTypeSymbol nt1 = (NamedTypeSymbol)t1.Type;
                        NamedTypeSymbol nt2 = (NamedTypeSymbol)t2.Type;

                        if (nt1.IsTupleType)
                        {
                            if (!nt2.IsTupleType)
                            {
                                return false;
                            }

                            return CanUnifyHelper(new TypeWithModifiers(nt1.TupleUnderlyingType), new TypeWithModifiers(nt2.TupleUnderlyingType), ref substitution);
                        }

                        if (!nt1.IsGenericType)
                        {
                            return !nt2.IsGenericType && nt1 == nt2;
                        }
                        else if (!nt2.IsGenericType)
                        {
                            return false;
                        }

                        int arity = nt1.Arity;

                        if (nt2.Arity != arity || nt2.OriginalDefinition != nt1.OriginalDefinition)
                        {
                            return false;
                        }

                        var nt1Arguments = nt1.TypeArgumentsNoUseSiteDiagnostics;
                        var nt2Arguments = nt2.TypeArgumentsNoUseSiteDiagnostics;

                        var nt1HasModifiers = nt1.HasTypeArgumentsCustomModifiers;
                        var nt2HasModifiers = nt2.HasTypeArgumentsCustomModifiers;

                        for (int i = 0; i < arity; i++)
                        {
                            if (!CanUnifyHelper(new TypeWithModifiers(nt1Arguments[i], nt1HasModifiers ? nt1.GetTypeArgumentCustomModifiers(i) : default(ImmutableArray<CustomModifier>)),
                                                new TypeWithModifiers(nt2Arguments[i], nt2HasModifiers ? nt2.GetTypeArgumentCustomModifiers(i) : default(ImmutableArray<CustomModifier>)),
                                                ref substitution))
                            {
                                return false;
                            }
                        }

                        // Note: Dev10 folds this into the loop since GetTypeArgsAll includes type args for containing types
                        // TODO: Calling CanUnifyHelper for the containing type is an overkill, we simply need to go through type arguments for all containers.
                        return (object)nt1.ContainingType == null || CanUnifyHelper(new TypeWithModifiers(nt1.ContainingType), new TypeWithModifiers(nt2.ContainingType), ref substitution);
                    }
                case SymbolKind.TypeParameter:
                    {
                        // These substitutions are not allowed in C#
                        if (t2.Type.TypeKind == TypeKind.Pointer || t2.Type.SpecialType == SpecialType.System_Void)
                        {
                            return false;
                        }

                        TypeParameterSymbol tp1 = (TypeParameterSymbol)t1.Type;

                        // Perform the "occurs check" - i.e. ensure that t2 doesn't contain t1 to avoid recursive types
                        // Note: t2 can't be the same type param - we would have caught that with ReferenceEquals above
                        if (Contains(t2.Type, tp1))
                        {
                            return false;
                        }

                        if (t1.CustomModifiers.IsDefaultOrEmpty)
                        {
                            AddSubstitution(ref substitution, tp1, t2);
                            return true;
                        }

                        if (t1.CustomModifiers.SequenceEqual(t2.CustomModifiers))
                        {
                            AddSubstitution(ref substitution, tp1, new TypeWithModifiers(t2.Type));
                            return true;
                        }

                        if (t1.CustomModifiers.Length < t2.CustomModifiers.Length &&
                            t1.CustomModifiers.SequenceEqual(t2.CustomModifiers.Take(t1.CustomModifiers.Length)))
                        {
                            AddSubstitution(ref substitution, tp1,
                                            new TypeWithModifiers(t2.Type,
                                                                  ImmutableArray.Create(t2.CustomModifiers, t1.CustomModifiers.Length, t2.CustomModifiers.Length - t1.CustomModifiers.Length)));
                            return true;
                        }

                        if (t2.Type.IsTypeParameter())
                        {
                            var tp2 = (TypeParameterSymbol)t2.Type;

                            if (t2.CustomModifiers.IsDefaultOrEmpty)
                            {
                                AddSubstitution(ref substitution, tp2, t1);
                                return true;
                            }

                            if (t2.CustomModifiers.Length < t1.CustomModifiers.Length &&
                                t2.CustomModifiers.SequenceEqual(t1.CustomModifiers.Take(t2.CustomModifiers.Length)))
                            {
                                AddSubstitution(ref substitution, tp2,
                                                new TypeWithModifiers(t1.Type,
                                                                      ImmutableArray.Create(t1.CustomModifiers, t2.CustomModifiers.Length, t1.CustomModifiers.Length - t2.CustomModifiers.Length)));
                                return true;
                            }
                        }

                        return false;
                    }
                default:
                    {
                        return t1 == t2;
                    }
            }
        }
        private static void AddSubstitution(ref MutableTypeMap substitution, TypeParameterSymbol tp1, TypeWithModifiers t2)
        {
            if (substitution == null)
            {
                substitution = new MutableTypeMap();
            }

            // MutableTypeMap.Add will throw if the key has already been added.  However,
            // if t1 was already in the substitution, it would have been substituted at the
            // start of CanUnifyHelper and we wouldn't be here.
            substitution.Add(tp1, t2);
        }
        /// <summary>
        /// Determine whether there is any substitution of type parameters that will
        /// make two types identical.
        /// </summary>
        /// <param name="t1">LHS</param>
        /// <param name="t2">RHS</param>
        /// <param name="substitution">
        /// Substitutions performed so far (or null for none).
        /// Keys are type parameters, values are types (possibly type parameters).
        /// Will be updated with new subsitutions by the callee.
        /// Should be ignored when false is returned.
        /// </param>
        /// <returns>True if there exists a type map such that Map(LHS) == Map(RHS).</returns>
        /// <remarks>
        /// Derived from Dev10's BSYMMGR::UnifyTypes.
        /// Two types will not unify if they have different custom modifiers.
        /// </remarks>
        private static bool CanUnifyHelper(TypeSymbol t1, TypeSymbol t2, ref MutableTypeMap substitution)
        {
            if (ReferenceEquals(t1, t2))
            {
                return true;
            }
            else if ((object)t1 == null || (object)t2 == null)
            {
                // Can't both be null or they would have been ReferenceEquals
                return false;
            }

            if (substitution != null)
            {
                t1 = substitution.SubstituteType(t1);
                t2 = substitution.SubstituteType(t2);
            }

            // If one of the types is a type parameter, then the substitution could make them ReferenceEquals.
            if (ReferenceEquals(t1, t2))
            {
                return true;
            }

            // We can avoid a lot of redundant checks if we ensure that we only have to check
            // for type parameters on the LHS
            if (!t1.IsTypeParameter() && t2.IsTypeParameter())
            {
                TypeSymbol tmp = t1;
                t1 = t2;
                t2 = tmp;
            }

            // If t1 is not a type parameter, then neither is t2
            Debug.Assert(t1.IsTypeParameter() || !t2.IsTypeParameter());

            switch (t1.Kind)
            {
                case SymbolKind.ArrayType:
                    {
                        if (t2.TypeKind != t1.TypeKind)
                        {
                            return false;
                        }

                        ArrayTypeSymbol at1 = (ArrayTypeSymbol)t1;
                        ArrayTypeSymbol at2 = (ArrayTypeSymbol)t2;

                        if (at1.Rank != at2.Rank || !at1.CustomModifiers.SequenceEqual(at2.CustomModifiers))
                        {
                            return false;
                        }

                        return CanUnifyHelper(at1.ElementType, at2.ElementType, ref substitution);
                    }
                case SymbolKind.PointerType:
                    {
                        if (t2.TypeKind != t1.TypeKind)
                        {
                            return false;
                        }

                        PointerTypeSymbol pt1 = (PointerTypeSymbol)t1;
                        PointerTypeSymbol pt2 = (PointerTypeSymbol)t2;

                        if (!pt1.CustomModifiers.SequenceEqual(pt2.CustomModifiers))
                        {
                            return false;
                        }

                        return CanUnifyHelper(pt1.PointedAtType, pt2.PointedAtType, ref substitution);
                    }
                case SymbolKind.NamedType:
                case SymbolKind.ErrorType:
                    {
                        if (t2.TypeKind != t1.TypeKind)
                        {
                            return false;
                        }

                        NamedTypeSymbol nt1 = (NamedTypeSymbol)t1;
                        NamedTypeSymbol nt2 = (NamedTypeSymbol)t2;

                        if (!nt1.IsGenericType)
                        {
                            return !nt2.IsGenericType && nt1 == nt2;
                        }
                        else if (!nt2.IsGenericType)
                        {
                            return false;
                        }

                        int arity = nt1.Arity;

                        if (nt2.Arity != arity || nt2.OriginalDefinition != nt1.OriginalDefinition)
                        {
                            return false;
                        }

                        for (int i = 0; i < arity; i++)
                        {
                            if (!CanUnifyHelper(nt1.TypeArgumentsNoUseSiteDiagnostics[i], nt2.TypeArgumentsNoUseSiteDiagnostics[i], ref substitution))
                            {
                                return false;
                            }
                        }

                        // Note: Dev10 folds this into the loop since GetTypeArgsAll includes type args for containing types
                        return (object)nt1.ContainingType == null || CanUnifyHelper(nt1.ContainingType, nt2.ContainingType, ref substitution);
                    }
                case SymbolKind.TypeParameter:
                    {
                        // These substitutions are not allowed in C#
                        if (t2.TypeKind == TypeKind.Pointer || t2.SpecialType == SpecialType.System_Void)
                        {
                            return false;
                        }

                        TypeParameterSymbol tp1 = (TypeParameterSymbol)t1;

                        // Perform the "occurs check" - i.e. ensure that t2 doesn't contain t1 to avoid recursive types
                        // Note: t2 can't be the same type param - we would have caught that with ReferenceEquals above
                        if (Contains(t2, tp1))
                        {
                            return false;
                        }

                        if (substitution == null)
                        {
                            substitution = new MutableTypeMap();
                        }

                        // MutableTypeMap.Add will throw if the key has already been added.  However,
                        // if t1 was already in the substitution, it would have been substituted at the
                        // start of this method and we wouldn't be here.
                        substitution.Add(tp1, t2);

                        return true;
                    }
                default:
                    {
                        return t1 == t2;
                    }
            }
        }
 private static void AppendMapping(MutableTypeMap customTypeSubstitution, NamedTypeSymbol namedTypeSymbol, bool invert = false)
 {
     for (var i = 0; i < namedTypeSymbol.TypeParameters.Length; i++)
     {
         var typeParameterSymbol = namedTypeSymbol.TypeParameters[i];
         var typeArgument = namedTypeSymbol.TypeArguments[i];
         if (!ReferenceEquals(typeParameterSymbol, typeArgument))
         {
             if (invert)
             {
                 Debug.Assert(typeArgument is TypeParameterSymbol, "TypeParameterSymbol is required");
                 customTypeSubstitution.Add(typeArgument as TypeParameterSymbol, customTypeSubstitution.SubstituteType(typeParameterSymbol));
             }
             else
             {
                 customTypeSubstitution.Add(typeParameterSymbol, typeArgument);
             }
         }
     }
 }
 private static void AppendMethodDirectMapping(MutableTypeMap customTypeSubstitution, MethodSymbol methodSymbolSpec, MethodSymbol methodSymbolDef)
 {
     for (var i = 0; i < methodSymbolSpec.TypeParameters.Length; i++)
     {
         var typeParameterSymbol = methodSymbolDef.TypeParameters[i];
         var typeArgument = methodSymbolSpec.TypeArguments[i];
         if (!ReferenceEquals(typeParameterSymbol, typeArgument))
         {
             customTypeSubstitution.Add(typeParameterSymbol, typeArgument);
         }
     }
 }
        public static IGenericContext CreateCustomMap(IMethod methodDefinition, IMethod methodSpecialization, IMethod additionalMethodDefinition = null)
        {
            var context = new MetadataGenericContext();
            var customTypeSubstitution = new MutableTypeMap();

            var methodSpecAdapter = methodSpecialization as MetadataMethodAdapter;
            if (methodSpecAdapter != null)
            {
                var methodSymbolSpec = methodSpecAdapter.MethodDef;
                AppendMapping(customTypeSubstitution, methodSymbolSpec);
            }

            var methodDefAdapter = methodDefinition as MetadataMethodAdapter;
            if (methodDefAdapter != null)
            {
                var methodSymbolDef = methodDefAdapter.MethodDef;
                AppendMapping(customTypeSubstitution, methodSymbolDef, true);
            }

            if (additionalMethodDefinition != null)
            {
                var metadataMethodAdapter = additionalMethodDefinition as MetadataMethodAdapter;
                if (metadataMethodAdapter != null && methodSpecAdapter != null)
                {
                    var additionalMethodSymbolDef = metadataMethodAdapter.MethodDef;
                    AppendMethodDirectMapping(customTypeSubstitution, methodSpecAdapter.MethodDef, additionalMethodSymbolDef);
                }
            }

            context.CustomTypeSubstitution = customTypeSubstitution;
            return context;
        }