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linux-packaging-mono/mcs/mcs/typespec.cs
Xamarin Public Jenkins (auto-signing) 6db692b74b Imported Upstream version 5.10.0.78 
Former-commit-id: 46737382176d7b811604042c613d5df6eef74f33
2018-01-31 19:21:06 +00:00

2169 lines
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//
// typespec.cs: Type specification
//
// Authors: Marek Safar (marek.safar@gmail.com)
//
// Dual licensed under the terms of the MIT X11 or GNU GPL
//
// Copyright 2010 Novell, Inc
// Copyright 2011 Xamarin, Inc (http://www.xamarin.com)
//
using System;
using System.Collections.Generic;
using System.Text;
using System.Linq;
#if STATIC
using MetaType = IKVM.Reflection.Type;
using IKVM.Reflection;
#else
using MetaType = System.Type;
using System.Reflection;
#endif
namespace Mono.CSharp
{
//
// Inflated or non-inflated representation of any type.
//
public class TypeSpec : MemberSpec
{
protected MetaType info;
protected MemberCache cache;
protected IList<TypeSpec> ifaces;
TypeSpec base_type;
Dictionary<TypeSpec[], InflatedTypeSpec> inflated_instances;
public static readonly TypeSpec[] EmptyTypes = new TypeSpec[0];
#if !STATIC
// Reflection Emit hacking
static readonly Type TypeBuilder;
static readonly Type GenericTypeBuilder;
static TypeSpec ()
{
var assembly = typeof (object).Assembly;
TypeBuilder = assembly.GetType ("System.Reflection.Emit.TypeBuilder");
GenericTypeBuilder = assembly.GetType ("System.Reflection.MonoGenericClass");
if (GenericTypeBuilder == null)
GenericTypeBuilder = assembly.GetType ("System.Reflection.Emit.TypeBuilderInstantiation");
}
#endif
public TypeSpec (MemberKind kind, TypeSpec declaringType, ITypeDefinition definition, MetaType info, Modifiers modifiers)
: base (kind, declaringType, definition, modifiers)
{
this.declaringType = declaringType;
this.info = info;
if (definition != null && definition.TypeParametersCount > 0)
state |= StateFlags.IsGeneric;
}
#region Properties
public override int Arity {
get {
return MemberDefinition.TypeParametersCount;
}
}
public virtual TypeSpec BaseType {
get {
return base_type;
}
set {
base_type = value;
}
}
public virtual BuiltinTypeSpec.Type BuiltinType {
get {
return BuiltinTypeSpec.Type.None;
}
}
public bool HasDynamicElement {
get {
return (state & StateFlags.HasDynamicElement) != 0;
}
}
public bool HasNamedTupleElement {
get {
return (state & StateFlags.HasNamedTupleElement) != 0;
}
}
//
// Returns a list of all interfaces including
// interfaces from base type or base interfaces
//
public virtual IList<TypeSpec> Interfaces {
get {
if ((state & StateFlags.InterfacesImported) == 0) {
state |= StateFlags.InterfacesImported;
//
// Delay interfaces expansion to save memory and once all
// base types has been imported to avoid problems where
// interface references type before its base was imported
//
var imported = MemberDefinition as ImportedTypeDefinition;
if (imported != null && Kind != MemberKind.MissingType)
imported.DefineInterfaces (this);
}
return ifaces;
}
set {
ifaces = value;
}
}
public bool IsArray {
get {
return Kind == MemberKind.ArrayType;
}
}
public bool IsAttribute {
get {
if (!IsClass)
return false;
var type = this;
do {
if (type.BuiltinType == BuiltinTypeSpec.Type.Attribute)
return true;
if (type.IsGeneric)
return false;
type = type.base_type;
} while (type != null);
return false;
}
}
public bool IsInterface {
get {
return Kind == MemberKind.Interface;
}
}
public bool IsClass {
get {
return Kind == MemberKind.Class;
}
}
public bool IsConstantCompatible {
get {
if ((Kind & (MemberKind.Enum | MemberKind.Class | MemberKind.Interface | MemberKind.Delegate | MemberKind.ArrayType)) != 0)
return true;
switch (BuiltinType) {
case BuiltinTypeSpec.Type.Int:
case BuiltinTypeSpec.Type.UInt:
case BuiltinTypeSpec.Type.Long:
case BuiltinTypeSpec.Type.ULong:
case BuiltinTypeSpec.Type.Float:
case BuiltinTypeSpec.Type.Double:
case BuiltinTypeSpec.Type.Char:
case BuiltinTypeSpec.Type.Short:
case BuiltinTypeSpec.Type.Decimal:
case BuiltinTypeSpec.Type.Bool:
case BuiltinTypeSpec.Type.SByte:
case BuiltinTypeSpec.Type.Byte:
case BuiltinTypeSpec.Type.UShort:
case BuiltinTypeSpec.Type.Dynamic:
return true;
}
return false;
}
}
public bool IsDelegate {
get {
return Kind == MemberKind.Delegate;
}
}
//
// Returns true for instances of Expression<T>
//
public virtual bool IsExpressionTreeType {
get {
return false;
}
set {
state = value ? state | StateFlags.InflatedExpressionType : state & ~StateFlags.InflatedExpressionType;
}
}
public bool IsEnum {
get {
return Kind == MemberKind.Enum;
}
}
//
// Returns true for instances of IList<T>, IEnumerable<T>, ICollection<T>
//
public virtual bool IsArrayGenericInterface {
get {
return false;
}
set {
state = value ? state | StateFlags.GenericIterateInterface : state & ~StateFlags.GenericIterateInterface;
}
}
public bool IsByRefLike => (modifiers & Modifiers.REF) != 0;
//
// Returns true for instances of System.Threading.Tasks.Task<T>
//
public virtual bool IsGenericTask {
get {
return false;
}
set {
state = value ? state | StateFlags.GenericTask : state & ~StateFlags.GenericTask;
}
}
public bool IsReadOnly => (modifiers & Modifiers.READONLY) != 0;
//
// Returns true for instances of any System.ValueTuple<......> type
//
public virtual bool IsTupleType {
get {
return (state & StateFlags.Tuple) != 0;
}
set {
state = value ? state | StateFlags.Tuple : state & ~StateFlags.Tuple;
}
}
// TODO: Should probably do
// IsGenericType -- recursive
// HasTypeParameter -- non-recursive
public bool IsGenericOrParentIsGeneric {
get {
var ts = this;
do {
if (ts.IsGeneric)
return true;
ts = ts.declaringType;
} while (ts != null);
return false;
}
}
public bool IsGenericParameter {
get {
return Kind == MemberKind.TypeParameter;
}
}
//
// Returns true for instances of Nullable<T>
//
public virtual bool IsNullableType {
get {
return false;
}
set {
state = value ? state | StateFlags.InflatedNullableType : state & ~StateFlags.InflatedNullableType;
}
}
public bool IsNested {
get { return declaringType != null && Kind != MemberKind.TypeParameter; }
}
public bool IsPointer {
get {
return Kind == MemberKind.PointerType;
}
}
public bool IsSealed {
get { return (Modifiers & Modifiers.SEALED) != 0; }
}
public bool IsSpecialRuntimeType {
get {
return (state & StateFlags.SpecialRuntimeType) != 0;
}
set {
state = value ? state | StateFlags.SpecialRuntimeType : state & ~StateFlags.SpecialRuntimeType;
}
}
public bool IsStruct {
get {
return Kind == MemberKind.Struct;
}
}
public bool IsStructOrEnum {
get {
return (Kind & (MemberKind.Struct | MemberKind.Enum)) != 0;
}
}
public bool IsTypeBuilder {
get {
#if STATIC
return true;
#else
var meta = GetMetaInfo().GetType ();
return meta == TypeBuilder || meta == GenericTypeBuilder;
#endif
}
}
//
// Whether a type is unmanaged. This is used by the unsafe code
//
public bool IsUnmanaged {
get {
if (IsPointer)
return ((ElementTypeSpec) this).Element.IsUnmanaged;
var ds = MemberDefinition as TypeDefinition;
if (ds != null)
return ds.IsUnmanagedType ();
if (Kind == MemberKind.Void)
return true;
if (Kind == MemberKind.TypeParameter)
return false;
if (IsNested && DeclaringType.IsGenericOrParentIsGeneric)
return false;
return IsValueType (this);
}
}
//
// A cache of all type members (including nested types)
//
public MemberCache MemberCache {
get {
if (cache == null || (state & StateFlags.PendingMemberCacheMembers) != 0)
InitializeMemberCache (false);
return cache;
}
set {
if (cache != null)
throw new InternalErrorException ("Membercache reset");
cache = value;
}
}
public MemberCache MemberCacheTypes {
get {
if (cache == null)
InitializeMemberCache (true);
return cache;
}
}
public new ITypeDefinition MemberDefinition {
get {
return (ITypeDefinition) definition;
}
}
// TODO: Wouldn't be better to rely on cast to InflatedTypeSpec and
// remove the property, YES IT WOULD !!!
public virtual TypeSpec[] TypeArguments {
get { return TypeSpec.EmptyTypes; }
}
#endregion
public virtual bool AddInterface (TypeSpec iface)
{
if ((state & StateFlags.InterfacesExpanded) != 0)
throw new InternalErrorException ("Modifying expanded interface list");
if (ifaces == null) {
ifaces = new List<TypeSpec> { iface };
return true;
}
if (!ifaces.Contains (iface)) {
ifaces.Add (iface);
return true;
}
return false;
}
//
// Special version used during type definition
//
public bool AddInterfaceDefined (TypeSpec iface)
{
if (!AddInterface (iface))
return false;
//
// We can get into a situation where a type is inflated before
// its interfaces are resoved. Consider this situation
//
// class A<T> : X<A<int>>, IFoo {}
//
// When resolving base class of X`1 we inflate context type A`1
// All this happens before we even hit IFoo resolve. Without
// additional expansion any inside usage of A<T> would miss IFoo
// interface because it comes from early inflated A`1 definition.
//
if (inflated_instances != null) {
//
// Inflate only existing instances not any new instances added
// during AddInterface
//
var inflated_existing = inflated_instances.Values.ToArray ();
foreach (var inflated in inflated_existing) {
inflated.AddInterface (iface);
}
}
return true;
}
//
// Returns all type arguments, usefull for nested types
//
public static TypeSpec[] GetAllTypeArguments (TypeSpec type)
{
IList<TypeSpec> targs = TypeSpec.EmptyTypes;
do {
if (type.Arity > 0) {
if (targs.Count == 0) {
targs = type.TypeArguments;
} else {
var list = targs as List<TypeSpec> ?? new List<TypeSpec> (targs);
list.AddRange (type.TypeArguments);
targs = list;
}
}
type = type.declaringType;
} while (type != null);
return targs as TypeSpec[] ?? ((List<TypeSpec>) targs).ToArray ();
}
public AttributeUsageAttribute GetAttributeUsage (PredefinedAttribute pa)
{
if (Kind != MemberKind.Class)
throw new InternalErrorException ();
if (!pa.IsDefined)
return Attribute.DefaultUsageAttribute;
AttributeUsageAttribute aua = null;
var type = this;
while (type != null) {
aua = type.MemberDefinition.GetAttributeUsage (pa);
if (aua != null)
break;
type = type.BaseType;
}
return aua;
}
//
// Return metadata information used during emit to describe the type
//
public virtual MetaType GetMetaInfo ()
{
return info;
}
public virtual TypeSpec GetDefinition ()
{
return this;
}
//
// Text representation of type used by documentation writer
//
public sealed override string GetSignatureForDocumentation ()
{
return GetSignatureForDocumentation (false);
}
public virtual string GetSignatureForDocumentation (bool explicitName)
{
StringBuilder sb = new StringBuilder ();
if (IsNested) {
sb.Append (DeclaringType.GetSignatureForDocumentation (explicitName));
} else if (MemberDefinition.Namespace != null) {
sb.Append (explicitName ? MemberDefinition.Namespace.Replace ('.', '#') : MemberDefinition.Namespace);
}
if (sb.Length != 0)
sb.Append (explicitName ? "#" : ".");
sb.Append (Name);
if (Arity > 0) {
if (this is InflatedTypeSpec) {
sb.Append ("{");
for (int i = 0; i < Arity; ++i) {
if (i > 0)
sb.Append (",");
sb.Append (TypeArguments[i].GetSignatureForDocumentation (explicitName));
}
sb.Append ("}");
} else {
sb.Append ("`");
sb.Append (Arity.ToString ());
}
}
return sb.ToString ();
}
public override string GetSignatureForError ()
{
string s;
if (IsNested) {
s = DeclaringType.GetSignatureForError ();
} else if (MemberDefinition is AnonymousTypeClass) {
return ((AnonymousTypeClass)MemberDefinition).GetSignatureForError ();
} else if (IsTupleType) {
return FormatTupleSignature ();
} else {
s = MemberDefinition.Namespace;
}
if (!string.IsNullOrEmpty (s))
s += ".";
return s + Name + GetTypeNameSignature ();
}
string FormatTupleSignature ()
{
var sb = new StringBuilder ();
sb.Append ("(");
for (int i = 0; i < TypeArguments.Length; ++i) {
if (i != 0)
sb.Append (", ");
sb.Append (TypeArguments[i].GetSignatureForError ());
}
sb.Append (")");
return sb.ToString ();
}
public string GetSignatureForErrorIncludingAssemblyName ()
{
var imported = MemberDefinition.DeclaringAssembly as ImportedAssemblyDefinition;
var location = imported != null ?
System.IO.Path.GetFullPath (imported.Location) :
((MemberCore)MemberDefinition).Location.NameFullPath;
return string.Format ("{0} [{1} -- {2}]", GetSignatureForError (),
MemberDefinition.DeclaringAssembly.FullName,
location);
}
protected virtual string GetTypeNameSignature ()
{
if (!IsGeneric)
return null;
return "<" + TypeManager.CSharpName (MemberDefinition.TypeParameters) + ">";
}
public bool ImplementsInterface (TypeSpec iface, bool variantly)
{
var ifaces = Interfaces;
if (ifaces != null) {
for (int i = 0; i < ifaces.Count; ++i) {
if (TypeSpecComparer.IsEqual (ifaces[i], iface))
return true;
if (variantly && TypeSpecComparer.Variant.IsEqual (ifaces[i], iface))
return true;
}
}
return false;
}
protected virtual void InitializeMemberCache (bool onlyTypes)
{
try {
MemberDefinition.LoadMembers (this, onlyTypes, ref cache);
} catch (Exception e) {
throw new InternalErrorException (e, "Unexpected error when loading type `{0}'", GetSignatureForError ());
}
if (onlyTypes)
state |= StateFlags.PendingMemberCacheMembers;
else
state &= ~StateFlags.PendingMemberCacheMembers;
}
//
// Is @baseClass base implementation of @type. With enabled @dynamicIsEqual the slower
// comparison is used to hide differences between `object' and `dynamic' for generic
// types. Should not be used for comparisons where G<object> != G<dynamic>
//
public static bool IsBaseClass (TypeSpec type, TypeSpec baseClass, bool dynamicIsObject)
{
if (dynamicIsObject && baseClass.IsGeneric) {
//
// Returns true for a hierarchies like this when passing baseClass of A<dynamic>
//
// class B : A<object> {}
//
type = type.BaseType;
while (type != null) {
if (TypeSpecComparer.IsEqual (type, baseClass))
return true;
type = type.BaseType;
}
return false;
}
while (type != null) {
type = type.BaseType;
if (type == baseClass)
return true;
}
return false;
}
public static bool IsReferenceType (TypeSpec t)
{
switch (t.Kind) {
case MemberKind.TypeParameter:
return ((TypeParameterSpec) t).IsReferenceType;
case MemberKind.Struct:
case MemberKind.Enum:
case MemberKind.Void:
case MemberKind.PointerType:
return false;
case MemberKind.InternalCompilerType:
//
// Null is considered to be a reference type
//
return t == InternalType.NullLiteral || t.BuiltinType == BuiltinTypeSpec.Type.Dynamic;
default:
return true;
}
}
public static bool IsNonNullableValueType (TypeSpec t)
{
switch (t.Kind) {
case MemberKind.TypeParameter:
return ((TypeParameterSpec) t).IsValueType;
case MemberKind.Struct:
return !t.IsNullableType;
case MemberKind.Enum:
return true;
default:
return false;
}
}
public static bool IsValueType (TypeSpec t)
{
switch (t.Kind) {
case MemberKind.TypeParameter:
return ((TypeParameterSpec) t).IsValueType;
case MemberKind.Struct:
case MemberKind.Enum:
return true;
default:
return false;
}
}
public override MemberSpec InflateMember (TypeParameterInflator inflator)
{
var targs = IsGeneric ? MemberDefinition.TypeParameters : TypeSpec.EmptyTypes;
//
// When inflating nested type from inside the type instance will be same
// because type parameters are same for all nested types
//
if (DeclaringType == inflator.TypeInstance) {
return MakeGenericType (inflator.Context, targs);
}
return new InflatedTypeSpec (inflator.Context, this, inflator.TypeInstance, targs);
}
//
// Inflates current type using specific type arguments
//
public InflatedTypeSpec MakeGenericType (IModuleContext context, TypeSpec[] targs)
{
if (targs.Length == 0 && !IsNested)
throw new ArgumentException ("Empty type arguments for type " + GetSignatureForError ());
InflatedTypeSpec instance;
if (inflated_instances == null) {
inflated_instances = new Dictionary<TypeSpec[], InflatedTypeSpec> (TypeSpecComparer.Default);
if (IsNested) {
instance = this as InflatedTypeSpec;
if (instance != null) {
//
// Nested types could be inflated on already inflated instances
// Caching this type ensured we are using same instance for
// inside/outside inflation using local type parameters
//
inflated_instances.Add (TypeArguments, instance);
}
}
}
if (!inflated_instances.TryGetValue (targs, out instance)) {
if (GetDefinition () != this && !IsNested)
throw new InternalErrorException ("`{0}' must be type definition or nested non-inflated type to MakeGenericType",
GetSignatureForError ());
instance = new InflatedTypeSpec (context, this, declaringType, targs);
inflated_instances.Add (targs, instance);
}
return instance;
}
public virtual TypeSpec Mutate (TypeParameterMutator mutator)
{
return this;
}
public override List<MissingTypeSpecReference> ResolveMissingDependencies (MemberSpec caller)
{
List<MissingTypeSpecReference> missing = null;
if (Kind == MemberKind.MissingType) {
missing = new List<MissingTypeSpecReference> ();
missing.Add (new MissingTypeSpecReference (this, caller));
return missing;
}
foreach (var targ in TypeArguments) {
if (targ.Kind == MemberKind.MissingType) {
if (missing == null)
missing = new List<MissingTypeSpecReference> ();
missing.Add (new MissingTypeSpecReference (targ, caller));
}
}
if (Interfaces != null) {
foreach (var iface in Interfaces) {
if (iface.Kind == MemberKind.MissingType) {
if (missing == null)
missing = new List<MissingTypeSpecReference> ();
missing.Add (new MissingTypeSpecReference (iface, caller));
}
}
}
if (MemberDefinition.TypeParametersCount > 0) {
foreach (var tp in MemberDefinition.TypeParameters) {
var tp_missing = tp.GetMissingDependencies (this);
if (tp_missing != null) {
if (missing == null)
missing = new List<MissingTypeSpecReference> ();
missing.AddRange (tp_missing);
}
}
}
if (missing != null || BaseType == null)
return missing;
return BaseType.ResolveMissingDependencies (this);
}
public void SetMetaInfo (MetaType info)
{
if (this.info != null)
throw new InternalErrorException ("MetaInfo reset");
this.info = info;
}
public void SetExtensionMethodContainer ()
{
modifiers |= Modifiers.METHOD_EXTENSION;
}
public void UpdateInflatedInstancesBaseType ()
{
//
// When nested class has a partial part the situation where parent type
// is inflated before its base type is defined can occur. In such case
// all inflated (should be only 1) instansted need to be updated
//
// partial class A<T> {
// partial class B : A<int> { }
// }
//
// partial class A<T> : X {}
//
if (inflated_instances == null)
return;
foreach (var inflated in inflated_instances) {
//
// Don't need to inflate possible generic type because for now the method
// is always used from within the nested type
//
inflated.Value.BaseType = base_type;
}
}
}
//
// Special version used for types which must exist in corlib or
// the compiler cannot work
//
public sealed class BuiltinTypeSpec : TypeSpec
{
public enum Type
{
None = 0,
// Ordered carefully for fast compares
FirstPrimitive = 1,
Bool = 1,
Byte = 2,
SByte = 3,
Char = 4,
Short = 5,
UShort = 6,
Int = 7,
UInt = 8,
Long = 9,
ULong = 10,
Float = 11,
Double = 12,
LastPrimitive = 12,
Decimal = 13,
IntPtr = 14,
UIntPtr = 15,
Object = 16,
Dynamic = 17,
String = 18,
Type = 19,
ValueType = 20,
Enum = 21,
Delegate = 22,
MulticastDelegate = 23,
Array = 24,
IEnumerator,
IEnumerable,
IDisposable,
Exception,
Attribute,
Other,
}
readonly Type type;
readonly string ns;
readonly string name;
public BuiltinTypeSpec (MemberKind kind, string ns, string name, Type builtinKind)
: base (kind, null, null, null, Modifiers.PUBLIC)
{
this.type = builtinKind;
this.ns = ns;
this.name = name;
}
public BuiltinTypeSpec (string name, Type builtinKind)
: this (MemberKind.InternalCompilerType, "", name, builtinKind)
{
// Make all internal types CLS-compliant, non-obsolete, compact
state = (state & ~(StateFlags.CLSCompliant_Undetected | StateFlags.Obsolete_Undetected | StateFlags.MissingDependency_Undetected)) | StateFlags.CLSCompliant;
}
#region Properties
public override int Arity {
get {
return 0;
}
}
public override BuiltinTypeSpec.Type BuiltinType {
get {
return type;
}
}
public string FullName {
get {
return ns + '.' + name;
}
}
public override string Name {
get {
return name;
}
}
public string Namespace {
get {
return ns;
}
}
#endregion
public static bool IsPrimitiveType (TypeSpec type)
{
return type.BuiltinType >= Type.FirstPrimitive && type.BuiltinType <= Type.LastPrimitive;
}
public static bool IsPrimitiveTypeOrDecimal (TypeSpec type)
{
return type.BuiltinType >= Type.FirstPrimitive && type.BuiltinType <= Type.Decimal;
}
public override string GetSignatureForError ()
{
switch (Name) {
case "Int32": return "int";
case "Int64": return "long";
case "String": return "string";
case "Boolean": return "bool";
case "Void": return "void";
case "Object": return "object";
case "UInt32": return "uint";
case "Int16": return "short";
case "UInt16": return "ushort";
case "UInt64": return "ulong";
case "Single": return "float";
case "Double": return "double";
case "Decimal": return "decimal";
case "Char": return "char";
case "Byte": return "byte";
case "SByte": return "sbyte";
}
if (ns.Length == 0)
return name;
return FullName;
}
//
// Returns the size of type if known, otherwise, 0
//
public static int GetSize (TypeSpec type)
{
switch (type.BuiltinType) {
case Type.Int:
case Type.UInt:
case Type.Float:
return 4;
case Type.Long:
case Type.ULong:
case Type.Double:
return 8;
case Type.Byte:
case Type.SByte:
case Type.Bool:
return 1;
case Type.Short:
case Type.Char:
case Type.UShort:
return 2;
case Type.Decimal:
return 16;
default:
return 0;
}
}
public void SetDefinition (ITypeDefinition td, MetaType type, Modifiers mod)
{
this.definition = td;
this.info = type;
this.modifiers |= (mod & ~Modifiers.AccessibilityMask);
}
public void SetDefinition (TypeSpec ts)
{
this.definition = ts.MemberDefinition;
this.info = ts.GetMetaInfo ();
this.BaseType = ts.BaseType;
this.Interfaces = ts.Interfaces;
this.modifiers = ts.Modifiers;
}
}
//
// Various type comparers used by compiler
//
static class TypeSpecComparer
{
//
// Does strict reference comparion only
//
public static readonly DefaultImpl Default = new DefaultImpl ();
public class DefaultImpl : IEqualityComparer<TypeSpec[]>
{
#region IEqualityComparer<TypeSpec[]> Members
bool IEqualityComparer<TypeSpec[]>.Equals (TypeSpec[] x, TypeSpec[] y)
{
if (x == y)
return true;
if (x.Length != y.Length)
return false;
for (int i = 0; i < x.Length; ++i)
if (x[i] != y[i])
return false;
return true;
}
int IEqualityComparer<TypeSpec[]>.GetHashCode (TypeSpec[] obj)
{
int hash = 0;
for (int i = 0; i < obj.Length; ++i)
hash = (hash << 5) - hash + obj[i].GetHashCode ();
return hash;
}
#endregion
}
//
// When comparing type signature of overrides or overloads
// this version tolerates different MVARs at same position
//
public static class Override
{
public static bool IsEqual (TypeSpec a, TypeSpec b)
{
if (a == b)
return true;
//
// Consider the following example:
//
// public abstract class A
// {
// public abstract T Foo<T>();
// }
//
// public class B : A
// {
// public override U Foo<T>() { return default (U); }
// }
//
// Here, `T' and `U' are method type parameters from different methods
// (A.Foo and B.Foo), so both `==' and Equals() will fail.
//
// However, since we're determining whether B.Foo() overrides A.Foo(),
// we need to do a signature based comparision and consider them equal.
//
var tp_a = a as TypeParameterSpec;
if (tp_a != null) {
var tp_b = b as TypeParameterSpec;
return tp_b != null && tp_a.IsMethodOwned == tp_b.IsMethodOwned && tp_a.DeclaredPosition == tp_b.DeclaredPosition;
}
var ac_a = a as ArrayContainer;
if (ac_a != null) {
var ac_b = b as ArrayContainer;
return ac_b != null && ac_a.Rank == ac_b.Rank && IsEqual (ac_a.Element, ac_b.Element);
}
if (a.BuiltinType == BuiltinTypeSpec.Type.Dynamic || b.BuiltinType == BuiltinTypeSpec.Type.Dynamic)
return b.BuiltinType == BuiltinTypeSpec.Type.Object || a.BuiltinType == BuiltinTypeSpec.Type.Object;
if (a.MemberDefinition != b.MemberDefinition)
return false;
do {
for (int i = 0; i < a.TypeArguments.Length; ++i) {
if (!IsEqual (a.TypeArguments[i], b.TypeArguments[i]))
return false;
}
a = a.DeclaringType;
b = b.DeclaringType;
} while (a != null);
return true;
}
public static bool IsEqual (TypeSpec[] a, TypeSpec[] b)
{
if (a == b)
return true;
if (a.Length != b.Length)
return false;
for (int i = 0; i < a.Length; ++i) {
if (!IsEqual (a[i], b[i]))
return false;
}
return true;
}
//
// Compares unordered arrays
//
public static bool IsSame (TypeSpec[] a, TypeSpec[] b)
{
if (a == b)
return true;
if (a == null || b == null || a.Length != b.Length)
return false;
for (int ai = 0; ai < a.Length; ++ai) {
bool found = false;
for (int bi = 0; bi < b.Length; ++bi) {
if (IsEqual (a[ai], b[bi])) {
found = true;
break;
}
}
if (!found)
return false;
}
return true;
}
public static bool IsEqual (AParametersCollection a, AParametersCollection b)
{
if (a == b)
return true;
if (a.Count != b.Count)
return false;
for (int i = 0; i < a.Count; ++i) {
if (!IsEqual (a.Types[i], b.Types[i]))
return false;
if ((a.FixedParameters[i].ModFlags & Parameter.Modifier.RefOutMask) != (b.FixedParameters[i].ModFlags & Parameter.Modifier.RefOutMask))
return false;
}
return true;
}
}
//
// Type variance equality comparison
//
public static class Variant
{
public static bool IsEqual (TypeSpec type1, TypeSpec type2)
{
if (!type1.IsGeneric || !type2.IsGeneric)
return false;
var target_type_def = type2.MemberDefinition;
if (type1.MemberDefinition != target_type_def)
return false;
var t1_targs = type1.TypeArguments;
var t2_targs = type2.TypeArguments;
var targs_definition = target_type_def.TypeParameters;
if (!type1.IsInterface && !type1.IsDelegate) {
return false;
}
for (int i = 0; i < targs_definition.Length; ++i) {
if (TypeSpecComparer.IsEqual (t1_targs[i], t2_targs[i]))
continue;
Variance v = targs_definition[i].Variance;
if (v == Variance.None) {
return false;
}
if (v == Variance.Covariant) {
if (!Convert.ImplicitReferenceConversionExists (t1_targs[i], t2_targs[i]))
return false;
} else if (!Convert.ImplicitReferenceConversionExists (t2_targs[i], t1_targs[i])) {
return false;
}
}
return true;
}
}
//
// Checks whether two generic instances may become equal for some
// particular instantiation (26.3.1).
//
public static class Unify
{
//
// Either @a or @b must be generic type
//
public static bool IsEqual (TypeSpec a, TypeSpec b)
{
if (a.MemberDefinition != b.MemberDefinition) {
var base_ifaces = a.Interfaces;
if (base_ifaces != null) {
foreach (var base_iface in base_ifaces) {
if (base_iface.Arity > 0 && IsEqual (base_iface, b))
return true;
}
}
return false;
}
var ta = a.TypeArguments;
var tb = b.TypeArguments;
for (int i = 0; i < ta.Length; i++) {
if (!MayBecomeEqualGenericTypes (ta[i], tb[i]))
return false;
}
if (a.IsNested && b.IsNested)
return IsEqual (a.DeclaringType, b.DeclaringType);
return true;
}
static bool ContainsTypeParameter (TypeSpec tparam, TypeSpec type)
{
TypeSpec[] targs = type.TypeArguments;
for (int i = 0; i < targs.Length; i++) {
if (tparam == targs[i])
return true;
if (ContainsTypeParameter (tparam, targs[i]))
return true;
}
return false;
}
/// <summary>
/// Check whether `a' and `b' may become equal generic types.
/// The algorithm to do that is a little bit complicated.
/// </summary>
static bool MayBecomeEqualGenericTypes (TypeSpec a, TypeSpec b)
{
if (a.IsGenericParameter) {
//
// If a is an array of a's type, they may never
// become equal.
//
if (b.IsArray)
return false;
//
// If b is a generic parameter or an actual type,
// they may become equal:
//
// class X<T,U> : I<T>, I<U>
// class X<T> : I<T>, I<float>
//
if (b.IsGenericParameter)
return a != b && a.DeclaringType == b.DeclaringType;
//
// We're now comparing a type parameter with a
// generic instance. They may become equal unless
// the type parameter appears anywhere in the
// generic instance:
//
// class X<T,U> : I<T>, I<X<U>>
// -> error because you could instanciate it as
// X<X<int>,int>
//
// class X<T> : I<T>, I<X<T>> -> ok
//
return !ContainsTypeParameter (a, b);
}
if (b.IsGenericParameter)
return MayBecomeEqualGenericTypes (b, a);
//
// At this point, neither a nor b are a type parameter.
//
// If one of them is a generic instance, compare them (if the
// other one is not a generic instance, they can never
// become equal).
//
if (TypeManager.IsGenericType (a) || TypeManager.IsGenericType (b))
return IsEqual (a, b);
//
// If both of them are arrays.
//
var a_ac = a as ArrayContainer;
if (a_ac != null) {
var b_ac = b as ArrayContainer;
if (b_ac == null || a_ac.Rank != b_ac.Rank)
return false;
return MayBecomeEqualGenericTypes (a_ac.Element, b_ac.Element);
}
//
// Ok, two ordinary types.
//
return false;
}
}
public static bool Equals (TypeSpec[] x, TypeSpec[] y)
{
if (x == y)
return true;
if (x.Length != y.Length)
return false;
for (int i = 0; i < x.Length; ++i)
if (!IsEqual (x[i], y[i]))
return false;
return true;
}
//
// Identity type conversion
//
// Default reference comparison, it has to be used when comparing
// two possible dynamic/internal types
//
public static bool IsEqual (TypeSpec a, TypeSpec b)
{
if (a == b) {
// This also rejects dynamic == dynamic
return a.Kind != MemberKind.InternalCompilerType || a.BuiltinType == BuiltinTypeSpec.Type.Dynamic;
}
if (a == null || b == null)
return false;
if (a.IsArray) {
var a_a = (ArrayContainer) a;
var b_a = b as ArrayContainer;
if (b_a == null)
return false;
return a_a.Rank == b_a.Rank && IsEqual (a_a.Element, b_a.Element);
}
if (!a.IsGeneric || !b.IsGeneric) {
//
// object and dynamic are considered equivalent there is an identity conversion
// between object and dynamic, and between constructed types that are the same
// when replacing all occurences of dynamic with object.
//
if (a.BuiltinType == BuiltinTypeSpec.Type.Dynamic || b.BuiltinType == BuiltinTypeSpec.Type.Dynamic)
return b.BuiltinType == BuiltinTypeSpec.Type.Object || a.BuiltinType == BuiltinTypeSpec.Type.Object;
return false;
}
if (a.MemberDefinition != b.MemberDefinition)
return false;
do {
if (!Equals (a.TypeArguments, b.TypeArguments))
return false;
a = a.DeclaringType;
b = b.DeclaringType;
} while (a != null);
return true;
}
}
public interface ITypeDefinition : IMemberDefinition
{
IAssemblyDefinition DeclaringAssembly { get; }
string Namespace { get; }
bool IsPartial { get; }
bool IsComImport { get; }
bool IsTypeForwarder { get; }
bool IsCyclicTypeForwarder { get; }
int TypeParametersCount { get; }
TypeParameterSpec[] TypeParameters { get; }
TypeSpec GetAsyncMethodBuilder ();
TypeSpec GetAttributeCoClass ();
string GetAttributeDefaultMember ();
AttributeUsageAttribute GetAttributeUsage (PredefinedAttribute pa);
bool IsInternalAsPublic (IAssemblyDefinition assembly);
void LoadMembers (TypeSpec declaringType, bool onlyTypes, ref MemberCache cache);
}
class InternalType : TypeSpec, ITypeDefinition
{
sealed class InternalTypeAssembly : IAssemblyDefinition
{
public static readonly InternalTypeAssembly Instance = new InternalTypeAssembly ();
public string FullName => throw new NotImplementedException ();
public bool IsCLSCompliant => false;
public bool IsMissing => false;
public string Name => throw new NotImplementedException ();
public byte [] GetPublicKeyToken ()
{
throw new NotImplementedException ();
}
public bool IsFriendAssemblyTo (IAssemblyDefinition assembly)
{
return false;
}
}
public static readonly InternalType AnonymousMethod = new InternalType ("anonymous method");
public static readonly InternalType Arglist = new InternalType ("__arglist");
public static readonly InternalType MethodGroup = new InternalType ("method group");
public static readonly InternalType NullLiteral = new InternalType ("null");
public static readonly InternalType FakeInternalType = new InternalType ("<fake$type>");
public static readonly InternalType Namespace = new InternalType ("<namespace>");
public static readonly InternalType ErrorType = new InternalType ("<error>");
public static readonly InternalType VarOutType = new InternalType ("var out");
public static readonly InternalType ThrowExpr = new InternalType ("throw expression");
public static readonly InternalType DefaultType = new InternalType ("default");
public static readonly InternalType Discard = new InternalType ("discard");
readonly string name;
InternalType (string name)
: base (MemberKind.InternalCompilerType, null, null, null, Modifiers.PUBLIC)
{
this.name = name;
this.definition = this;
cache = MemberCache.Empty;
// Make all internal types CLS-compliant, non-obsolete
state = (state & ~(StateFlags.CLSCompliant_Undetected | StateFlags.Obsolete_Undetected | StateFlags.MissingDependency_Undetected)) | StateFlags.CLSCompliant;
}
#region Properties
public override int Arity {
get {
return 0;
}
}
IAssemblyDefinition ITypeDefinition.DeclaringAssembly {
get {
return InternalTypeAssembly.Instance;
}
}
bool ITypeDefinition.IsComImport {
get {
return false;
}
}
bool IMemberDefinition.IsImported {
get {
return false;
}
}
bool ITypeDefinition.IsPartial {
get {
return false;
}
}
bool ITypeDefinition.IsTypeForwarder {
get {
return false;
}
}
bool ITypeDefinition.IsCyclicTypeForwarder {
get {
return false;
}
}
public override string Name {
get {
return name;
}
}
string ITypeDefinition.Namespace {
get {
return null;
}
}
int ITypeDefinition.TypeParametersCount {
get {
return 0;
}
}
TypeParameterSpec[] ITypeDefinition.TypeParameters {
get {
return null;
}
}
#endregion
public override string GetSignatureForError ()
{
return name;
}
#region ITypeDefinition Members
TypeSpec ITypeDefinition.GetAsyncMethodBuilder ()
{
return null;
}
TypeSpec ITypeDefinition.GetAttributeCoClass ()
{
return null;
}
string ITypeDefinition.GetAttributeDefaultMember ()
{
return null;
}
AttributeUsageAttribute ITypeDefinition.GetAttributeUsage (PredefinedAttribute pa)
{
return null;
}
bool ITypeDefinition.IsInternalAsPublic (IAssemblyDefinition assembly)
{
throw new NotImplementedException ();
}
void ITypeDefinition.LoadMembers (TypeSpec declaringType, bool onlyTypes, ref MemberCache cache)
{
throw new NotImplementedException ();
}
string[] IMemberDefinition.ConditionalConditions ()
{
return null;
}
ObsoleteAttribute IMemberDefinition.GetAttributeObsolete ()
{
return null;
}
bool? IMemberDefinition.CLSAttributeValue {
get {
return null;
}
}
void IMemberDefinition.SetIsAssigned ()
{
}
void IMemberDefinition.SetIsUsed ()
{
}
#endregion
public static bool HasNoType (TypeSpec type)
{
return type == AnonymousMethod || type == MethodGroup || type == NullLiteral || type == ThrowExpr || type == DefaultType;
}
}
//
// Common base class for composite types
//
public abstract class ElementTypeSpec : TypeSpec, ITypeDefinition
{
protected ElementTypeSpec (MemberKind kind, TypeSpec element, MetaType info)
: base (kind, element.DeclaringType, null, info, element.Modifiers)
{
this.Element = element;
state &= ~SharedStateFlags;
state |= (element.state & SharedStateFlags);
if (element.BuiltinType == BuiltinTypeSpec.Type.Dynamic)
state |= StateFlags.HasDynamicElement;
// Has to use its own type definition instead of just element definition to
// correctly identify itself for cases like x.MemberDefininition == predefined.MemberDefinition
this.definition = this;
cache = MemberCache.Empty;
}
#region Properties
public TypeSpec Element { get; private set; }
public override IList<TypeSpec> Interfaces {
set {
throw new NotSupportedException ();
}
}
bool ITypeDefinition.IsComImport {
get {
return false;
}
}
bool ITypeDefinition.IsPartial {
get {
return false;
}
}
bool ITypeDefinition.IsTypeForwarder {
get {
return false;
}
}
bool ITypeDefinition.IsCyclicTypeForwarder {
get {
return false;
}
}
public override string Name {
get {
throw new NotSupportedException ();
}
}
#endregion
public override void CheckObsoleteness (IMemberContext mc, Location loc)
{
Element.CheckObsoleteness (mc, loc);
}
public override ObsoleteAttribute GetAttributeObsolete ()
{
return Element.GetAttributeObsolete ();
}
protected virtual string GetPostfixSignature ()
{
return null;
}
public override string GetSignatureForDocumentation (bool explicitName)
{
return Element.GetSignatureForDocumentation (explicitName) + GetPostfixSignature ();
}
public override string GetSignatureForError ()
{
return Element.GetSignatureForError () + GetPostfixSignature ();
}
public override TypeSpec Mutate (TypeParameterMutator mutator)
{
var me = Element.Mutate (mutator);
if (me == Element)
return this;
var mutated = (ElementTypeSpec) MemberwiseClone ();
mutated.Element = me;
mutated.info = null;
return mutated;
}
#region ITypeDefinition Members
IAssemblyDefinition ITypeDefinition.DeclaringAssembly {
get {
return Element.MemberDefinition.DeclaringAssembly;
}
}
bool ITypeDefinition.IsInternalAsPublic (IAssemblyDefinition assembly)
{
return Element.MemberDefinition.IsInternalAsPublic (assembly);
}
public string Namespace {
get { throw new NotImplementedException (); }
}
public int TypeParametersCount {
get {
return 0;
}
}
public TypeParameterSpec[] TypeParameters {
get {
throw new NotSupportedException ();
}
}
public TypeSpec GetAsyncMethodBuilder ()
{
return null;
}
public TypeSpec GetAttributeCoClass ()
{
return Element.MemberDefinition.GetAttributeCoClass ();
}
public string GetAttributeDefaultMember ()
{
return Element.MemberDefinition.GetAttributeDefaultMember ();
}
public void LoadMembers (TypeSpec declaringType, bool onlyTypes, ref MemberCache cache)
{
Element.MemberDefinition.LoadMembers (declaringType, onlyTypes, ref cache);
}
public bool IsImported {
get {
return Element.MemberDefinition.IsImported;
}
}
public string[] ConditionalConditions ()
{
return Element.MemberDefinition.ConditionalConditions ();
}
bool? IMemberDefinition.CLSAttributeValue {
get {
return Element.MemberDefinition.CLSAttributeValue;
}
}
public void SetIsAssigned ()
{
Element.MemberDefinition.SetIsAssigned ();
}
public void SetIsUsed ()
{
Element.MemberDefinition.SetIsUsed ();
}
#endregion
}
public class ArrayContainer : ElementTypeSpec
{
public struct TypeRankPair : IEquatable<TypeRankPair>
{
TypeSpec ts;
int rank;
public TypeRankPair (TypeSpec ts, int rank)
{
this.ts = ts;
this.rank = rank;
}
public override int GetHashCode ()
{
return ts.GetHashCode () ^ rank.GetHashCode ();
}
#region IEquatable<Tuple<T1,T2>> Members
public bool Equals (TypeRankPair other)
{
return other.ts == ts && other.rank == rank;
}
#endregion
}
readonly int rank;
readonly ModuleContainer module;
ArrayContainer (ModuleContainer module, TypeSpec element, int rank)
: base (MemberKind.ArrayType, element, null)
{
this.module = module;
this.rank = rank;
}
public override IList<TypeSpec> Interfaces {
get {
return BaseType.Interfaces;
}
}
public int Rank {
get {
return rank;
}
}
public MethodInfo GetConstructor ()
{
var mb = module.Builder;
var arg_types = new MetaType[rank];
for (int i = 0; i < rank; i++)
arg_types[i] = module.Compiler.BuiltinTypes.Int.GetMetaInfo ();
var ctor = mb.GetArrayMethod (
GetMetaInfo (), Constructor.ConstructorName,
CallingConventions.HasThis,
null, arg_types);
return ctor;
}
public MethodInfo GetAddressMethod ()
{
var mb = module.Builder;
var arg_types = new MetaType[rank];
for (int i = 0; i < rank; i++)
arg_types[i] = module.Compiler.BuiltinTypes.Int.GetMetaInfo ();
var address = mb.GetArrayMethod (
GetMetaInfo (), "Address",
CallingConventions.HasThis | CallingConventions.Standard,
ReferenceContainer.MakeType (module, Element).GetMetaInfo (), arg_types);
return address;
}
public MethodInfo GetGetMethod ()
{
var mb = module.Builder;
var arg_types = new MetaType[rank];
for (int i = 0; i < rank; i++)
arg_types[i] = module.Compiler.BuiltinTypes.Int.GetMetaInfo ();
var get = mb.GetArrayMethod (
GetMetaInfo (), "Get",
CallingConventions.HasThis | CallingConventions.Standard,
Element.GetMetaInfo (), arg_types);
return get;
}
public MethodInfo GetSetMethod ()
{
var mb = module.Builder;
var arg_types = new MetaType[rank + 1];
for (int i = 0; i < rank; i++)
arg_types[i] = module.Compiler.BuiltinTypes.Int.GetMetaInfo ();
arg_types[rank] = Element.GetMetaInfo ();
var set = mb.GetArrayMethod (
GetMetaInfo (), "Set",
CallingConventions.HasThis | CallingConventions.Standard,
module.Compiler.BuiltinTypes.Void.GetMetaInfo (), arg_types);
return set;
}
public override MetaType GetMetaInfo ()
{
if (info == null) {
if (rank == 1)
info = Element.GetMetaInfo ().MakeArrayType ();
else
info = Element.GetMetaInfo ().MakeArrayType (rank);
}
return info;
}
protected override string GetPostfixSignature()
{
return GetPostfixSignature (rank);
}
public static string GetPostfixSignature (int rank)
{
StringBuilder sb = new StringBuilder ();
sb.Append ("[");
for (int i = 1; i < rank; i++) {
sb.Append (",");
}
sb.Append ("]");
return sb.ToString ();
}
public override string GetSignatureForDocumentation (bool explicitName)
{
StringBuilder sb = new StringBuilder ();
GetElementSignatureForDocumentation (sb, explicitName);
return sb.ToString ();
}
void GetElementSignatureForDocumentation (StringBuilder sb, bool explicitName)
{
var ac = Element as ArrayContainer;
if (ac == null)
sb.Append (Element.GetSignatureForDocumentation (explicitName));
else
ac.GetElementSignatureForDocumentation (sb, explicitName);
if (explicitName) {
sb.Append (GetPostfixSignature (rank));
} else {
sb.Append ("[");
for (int i = 1; i < rank; i++) {
if (i == 1)
sb.Append ("0:");
sb.Append (",0:");
}
sb.Append ("]");
}
}
public static ArrayContainer MakeType (ModuleContainer module, TypeSpec element)
{
return MakeType (module, element, 1);
}
public static ArrayContainer MakeType (ModuleContainer module, TypeSpec element, int rank)
{
ArrayContainer ac;
var key = new TypeRankPair (element, rank);
if (!module.ArrayTypesCache.TryGetValue (key, out ac)) {
ac = new ArrayContainer (module, element, rank);
ac.BaseType = module.Compiler.BuiltinTypes.Array;
module.ArrayTypesCache.Add (key, ac);
}
return ac;
}
public override List<MissingTypeSpecReference> ResolveMissingDependencies (MemberSpec caller)
{
return Element.ResolveMissingDependencies (caller);
}
}
[System.Diagnostics.DebuggerDisplay("{DisplayDebugInfo()}")]
class ReferenceContainer : ElementTypeSpec
{
protected ReferenceContainer (TypeSpec element)
: base (MemberKind.ByRef, element, null)
{
cache = null;
}
public override IList<TypeSpec> Interfaces {
get {
return null;
}
}
string DisplayDebugInfo()
{
return "ref " + GetSignatureForError();
}
public override MetaType GetMetaInfo ()
{
if (info == null) {
info = Element.GetMetaInfo ().MakeByRefType ();
}
return info;
}
public override string GetSignatureForError ()
{
return Element.GetSignatureForError ();
}
public static ReferenceContainer MakeType (ModuleContainer module, TypeSpec element)
{
if (element.Kind == MemberKind.ByRef)
throw new ArgumentException ();
ReferenceContainer pc;
if (!module.ReferenceTypesCache.TryGetValue (element, out pc)) {
pc = new ReferenceContainer (element);
module.ReferenceTypesCache.Add (element, pc);
}
return pc;
}
protected override void InitializeMemberCache(bool onlyTypes)
{
cache = Element.MemberCache;
}
}
[System.Diagnostics.DebuggerDisplay ("{DisplayDebugInfo()}")]
class ReadOnlyReferenceContainer : ReferenceContainer
{
public ReadOnlyReferenceContainer (TypeSpec element)
: base (element)
{
}
string DisplayDebugInfo ()
{
return "ref readonly " + GetSignatureForError ();
}
public new static ReferenceContainer MakeType (ModuleContainer module, TypeSpec element)
{
if (element.Kind == MemberKind.ByRef)
throw new ArgumentException ();
ReadOnlyReferenceContainer pc;
if (!module.ReadonlyReferenceTypesCache.TryGetValue (element, out pc)) {
pc = new ReadOnlyReferenceContainer (element);
module.ReadonlyReferenceTypesCache.Add (element, pc);
}
return pc;
}
}
class PointerContainer : ElementTypeSpec
{
private PointerContainer (TypeSpec element)
: base (MemberKind.PointerType, element, null)
{
// It's never CLS-Compliant
state &= ~StateFlags.CLSCompliant_Undetected;
}
public override IList<TypeSpec> Interfaces {
get {
return null;
}
}
public override MetaType GetMetaInfo ()
{
if (info == null) {
info = Element.GetMetaInfo ().MakePointerType ();
}
return info;
}
protected override string GetPostfixSignature()
{
return "*";
}
public static PointerContainer MakeType (ModuleContainer module, TypeSpec element)
{
PointerContainer pc;
if (!module.PointerTypesCache.TryGetValue (element, out pc)) {
pc = new PointerContainer (element);
module.PointerTypesCache.Add (element, pc);
}
return pc;
}
}
public class MissingTypeSpecReference
{
public MissingTypeSpecReference (TypeSpec type, MemberSpec caller)
{
Type = type;
Caller = caller;
}
public TypeSpec Type { get; private set; }
public MemberSpec Caller { get; private set; }
}
}
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