//
// decl.cs: Declaration base class for structs, classes, enums and interfaces.
//
// Author: Miguel de Icaza (miguel@gnu.org)
// Marek Safar (marek.safar@seznam.cz)
//
// Licensed under the terms of the GNU GPL
//
// (C) 2001 Ximian, Inc (http://www.ximian.com)
// (C) 2004 Novell, Inc
//
// TODO: Move the method verification stuff from the class.cs and interface.cs here
//
using System;
using System.Text;
using System.Collections;
using System.Globalization;
using System.Reflection.Emit;
using System.Reflection;
using System.Xml;
namespace Mono.CSharp {
public class MemberName {
public string Name;
public readonly TypeArguments TypeArguments;
public readonly MemberName Left;
public static readonly MemberName Null = new MemberName ("");
public MemberName (string name)
{
this.Name = name;
}
public MemberName (string name, TypeArguments args)
: this (name)
{
this.TypeArguments = args;
}
public MemberName (MemberName left, string name, TypeArguments args)
: this (name, args)
{
this.Left = left;
}
public MemberName (MemberName left, MemberName right)
: this (left, right.Name, right.TypeArguments)
{
}
public string GetName ()
{
if (Left != null)
return Left.GetName () + "." + Name;
else
return Name;
}
public bool IsGeneric {
get {
if (TypeArguments != null)
return true;
else if (Left != null)
return Left.IsGeneric;
else
return false;
}
}
public string GetName (bool is_generic)
{
string name = is_generic ? Basename : Name;
if (Left != null)
return Left.GetName (is_generic) + "." + name;
else
return name;
}
public int CountTypeArguments {
get {
if (TypeArguments == null)
return 0;
else
return TypeArguments.Count;
}
}
public string GetMethodName ()
{
if (Left != null)
return Left.GetTypeName () + "." + Name;
else
return Name;
}
public static string MakeName (string name, TypeArguments args)
{
if (args == null)
return name;
else
return name + "`" + args.Count;
}
public static string MakeName (string name, int count)
{
return name + "`" + count;
}
public string GetTypeName ()
{
if (Left != null)
return Left.GetTypeName () + "." +
MakeName (Name, TypeArguments);
else
return MakeName (Name, TypeArguments);
}
protected bool IsUnbound {
get {
if ((Left != null) && Left.IsUnbound)
return true;
else if (TypeArguments == null)
return false;
else
return TypeArguments.IsUnbound;
}
}
protected bool CheckUnbound (Location loc)
{
if ((Left != null) && !Left.CheckUnbound (loc))
return false;
if ((TypeArguments != null) && !TypeArguments.IsUnbound) {
Report.Error (1031, loc, "Type expected");
return false;
}
return true;
}
public Expression GetTypeExpression (Location loc)
{
if (IsUnbound) {
if (!CheckUnbound (loc))
return null;
return new UnboundTypeExpression (GetTypeName ());
}
if (Left != null) {
Expression lexpr = Left.GetTypeExpression (loc);
return new MemberAccess (lexpr, Name, TypeArguments, loc);
} else {
if (TypeArguments != null)
return new SimpleName (Basename, TypeArguments, loc);
else
return new SimpleName (Name, loc);
}
}
public MemberName Clone ()
{
if (Left != null)
return new MemberName (Left.Clone (), Name, TypeArguments);
else
return new MemberName (Name, TypeArguments);
}
public string Basename {
get {
if (TypeArguments != null)
return MakeName (Name, TypeArguments);
else
return Name;
}
}
public override string ToString ()
{
string full_name;
if (TypeArguments != null)
full_name = Name + "<" + TypeArguments + ">";
else
full_name = Name;
if (Left != null)
return Left + "." + full_name;
else
return full_name;
}
}
///
/// Base representation for members. This is used to keep track
/// of Name, Location and Modifier flags, and handling Attributes.
///
public abstract class MemberCore : Attributable {
///
/// Public name
///
public string Name {
get {
return MemberName.GetName (!(this is GenericMethod) && !(this is Method));
}
}
// Is not readonly because of IndexerName attribute
public MemberName MemberName;
///
/// Modifier flags that the user specified in the source code
///
public int ModFlags;
public /*readonly*/ TypeContainer Parent;
///
/// Location where this declaration happens
///
public readonly Location Location;
///
/// XML documentation comment
///
public string DocComment;
///
/// Represents header string for documentation comment
/// for each member types.
///
public abstract string DocCommentHeader { get; }
[Flags]
public enum Flags {
Obsolete_Undetected = 1, // Obsolete attribute has not been detected yet
Obsolete = 1 << 1, // Type has obsolete attribute
ClsCompliance_Undetected = 1 << 2, // CLS Compliance has not been detected yet
ClsCompliant = 1 << 3, // Type is CLS Compliant
CloseTypeCreated = 1 << 4, // Tracks whether we have Closed the type
HasCompliantAttribute_Undetected = 1 << 5, // Presence of CLSCompliantAttribute has not been detected
HasClsCompliantAttribute = 1 << 6, // Type has CLSCompliantAttribute
ClsCompliantAttributeTrue = 1 << 7, // Type has CLSCompliant (true)
Excluded_Undetected = 1 << 8, // Conditional attribute has not been detected yet
Excluded = 1 << 9, // Method is conditional
TestMethodDuplication = 1 << 10 // Test for duplication must be performed
}
///
/// MemberCore flags at first detected then cached
///
internal Flags caching_flags;
public MemberCore (TypeContainer parent, MemberName name, Attributes attrs,
Location loc)
: base (attrs)
{
if (parent is PartialContainer && !(this is PartialContainer))
throw new InternalErrorException ("A PartialContainer cannot be the direct parent of a member");
Parent = parent;
MemberName = name;
Location = loc;
caching_flags = Flags.Obsolete_Undetected | Flags.ClsCompliance_Undetected | Flags.HasCompliantAttribute_Undetected | Flags.Excluded_Undetected;
}
///
/// Tests presence of ObsoleteAttribute and report proper error
///
protected void CheckUsageOfObsoleteAttribute (Type type)
{
if (type == null)
return;
ObsoleteAttribute obsolete_attr = AttributeTester.GetObsoleteAttribute (type);
if (obsolete_attr == null)
return;
AttributeTester.Report_ObsoleteMessage (obsolete_attr, type.FullName, Location);
}
public abstract bool Define ();
//
// Returns full member name for error message
//
public virtual string GetSignatureForError ()
{
return Name;
}
///
/// Use this method when MethodBuilder is null
///
public virtual string GetSignatureForError (TypeContainer tc)
{
return Name;
}
///
/// Base Emit method. This is also entry point for CLS-Compliant verification.
///
public virtual void Emit ()
{
// Hack with Parent == null is for EnumMember
if (Parent == null || (GetObsoleteAttribute (Parent) == null && Parent.GetObsoleteAttribute (Parent) == null))
VerifyObsoleteAttribute ();
if (!RootContext.VerifyClsCompliance)
return;
VerifyClsCompliance (Parent);
}
public bool InUnsafe {
get {
return ((ModFlags & Modifiers.UNSAFE) != 0) || Parent.UnsafeContext;
}
}
//
// Whehter is it ok to use an unsafe pointer in this type container
//
public bool UnsafeOK (DeclSpace parent)
{
//
// First check if this MemberCore modifier flags has unsafe set
//
if ((ModFlags & Modifiers.UNSAFE) != 0)
return true;
if (parent.UnsafeContext)
return true;
Expression.UnsafeError (Location);
return false;
}
///
/// Returns instance of ObsoleteAttribute for this MemberCore
///
public ObsoleteAttribute GetObsoleteAttribute (DeclSpace ds)
{
// ((flags & (Flags.Obsolete_Undetected | Flags.Obsolete)) == 0) is slower, but why ?
if ((caching_flags & Flags.Obsolete_Undetected) == 0 && (caching_flags & Flags.Obsolete) == 0) {
return null;
}
caching_flags &= ~Flags.Obsolete_Undetected;
if (OptAttributes == null)
return null;
Attribute obsolete_attr = OptAttributes.Search (
TypeManager.obsolete_attribute_type, ds.EmitContext);
if (obsolete_attr == null)
return null;
ObsoleteAttribute obsolete = obsolete_attr.GetObsoleteAttribute (ds.EmitContext);
if (obsolete == null)
return null;
caching_flags |= Flags.Obsolete;
return obsolete;
}
///
/// Analyze whether CLS-Compliant verification must be execute for this MemberCore.
///
public override bool IsClsCompliaceRequired (DeclSpace container)
{
if ((caching_flags & Flags.ClsCompliance_Undetected) == 0)
return (caching_flags & Flags.ClsCompliant) != 0;
if (GetClsCompliantAttributeValue (container) && IsExposedFromAssembly (container)) {
caching_flags &= ~Flags.ClsCompliance_Undetected;
caching_flags |= Flags.ClsCompliant;
return true;
}
caching_flags &= ~Flags.ClsCompliance_Undetected;
return false;
}
///
/// Returns true when MemberCore is exposed from assembly.
///
public bool IsExposedFromAssembly (DeclSpace ds)
{
if ((ModFlags & (Modifiers.PUBLIC | Modifiers.PROTECTED)) == 0)
return false;
DeclSpace parentContainer = ds;
while (parentContainer != null && parentContainer.ModFlags != 0) {
if ((parentContainer.ModFlags & (Modifiers.PUBLIC | Modifiers.PROTECTED)) == 0)
return false;
parentContainer = parentContainer.Parent;
}
return true;
}
///
/// Resolve CLSCompliantAttribute value or gets cached value.
///
bool GetClsCompliantAttributeValue (DeclSpace ds)
{
if (OptAttributes != null) {
Attribute cls_attribute = OptAttributes.Search (
TypeManager.cls_compliant_attribute_type, ds.EmitContext);
if (cls_attribute != null) {
caching_flags |= Flags.HasClsCompliantAttribute;
return cls_attribute.GetClsCompliantAttributeValue (ds.EmitContext);
}
}
return ds.GetClsCompliantAttributeValue ();
}
///
/// Returns true if MemberCore is explicitly marked with CLSCompliantAttribute
///
protected bool HasClsCompliantAttribute {
get {
return (caching_flags & Flags.HasClsCompliantAttribute) != 0;
}
}
///
/// It helps to handle error 102 & 111 detection
///
public virtual bool MarkForDuplicationCheck ()
{
return false;
}
///
/// The main virtual method for CLS-Compliant verifications.
/// The method returns true if member is CLS-Compliant and false if member is not
/// CLS-Compliant which means that CLS-Compliant tests are not necessary. A descendants override it
/// and add their extra verifications.
///
protected virtual bool VerifyClsCompliance (DeclSpace ds)
{
if (!IsClsCompliaceRequired (ds)) {
if (HasClsCompliantAttribute && RootContext.WarningLevel >= 2) {
if (!IsExposedFromAssembly (ds))
Report.Warning (3019, Location, "CLS compliance checking will not be performed on '{0}' because it is private or internal", GetSignatureForError ());
if (!CodeGen.Assembly.IsClsCompliant)
Report.Warning (3021, Location, "'{0}' does not need a CLSCompliant attribute because the assembly does not have a CLSCompliant attribute", GetSignatureForError ());
}
return false;
}
if (!CodeGen.Assembly.IsClsCompliant) {
if (HasClsCompliantAttribute) {
Report.Error (3014, Location, "'{0}' cannot be marked as CLS-compliant because the assembly does not have a CLSCompliant attribute", GetSignatureForError ());
}
return false;
}
int index = Name.LastIndexOf ('.');
if (Name [index > 0 ? index + 1 : 0] == '_') {
Report.Error (3008, Location, "Identifier '{0}' is not CLS-compliant", GetSignatureForError () );
}
return true;
}
protected abstract void VerifyObsoleteAttribute ();
//
// Raised (and passed an XmlElement that contains the comment)
// when GenerateDocComment is writing documentation expectedly.
//
internal virtual void OnGenerateDocComment (DeclSpace ds, XmlElement intermediateNode)
{
}
//
// Returns a string that represents the signature for this
// member which should be used in XML documentation.
//
public virtual string GetDocCommentName (DeclSpace ds)
{
if (ds == null || this is DeclSpace)
return DocCommentHeader + Name;
else
return String.Concat (DocCommentHeader, ds.Name, ".", Name);
}
//
// Generates xml doc comments (if any), and if required,
// handle warning report.
//
internal virtual void GenerateDocComment (DeclSpace ds)
{
DocUtil.GenerateDocComment (this, ds);
}
}
///
/// Base class for structs, classes, enumerations and interfaces.
///
///
/// They all create new declaration spaces. This
/// provides the common foundation for managing those name
/// spaces.
///
public abstract class DeclSpace : MemberCore, IAlias {
///
/// This points to the actual definition that is being
/// created with System.Reflection.Emit
///
public TypeBuilder TypeBuilder;
///
/// If we are a generic type, this is the type we are
/// currently defining. We need to lookup members on this
/// instead of the TypeBuilder.
///
public Type CurrentType;
//
// This is the namespace in which this typecontainer
// was declared. We use this to resolve names.
//
public NamespaceEntry NamespaceEntry;
private Hashtable Cache = new Hashtable ();
public readonly string Basename;
public readonly string Basename_with_arity;
protected Hashtable defined_names;
readonly bool is_generic;
readonly int count_type_params;
readonly int count_current_type_params;
// The emit context for toplevel objects.
protected EmitContext ec;
public EmitContext EmitContext {
get { return ec; }
}
//
// Whether we are Generic
//
public bool IsGeneric {
get {
if (is_generic)
return true;
else if (Parent != null)
return Parent.IsGeneric;
else
return false;
}
}
static string[] attribute_targets = new string [] { "type" };
public DeclSpace (NamespaceEntry ns, TypeContainer parent, MemberName name,
Attributes attrs, Location l)
: base (parent, name, attrs, l)
{
NamespaceEntry = ns;
Basename = name.Name;
Basename_with_arity = name.Basename;
defined_names = new Hashtable ();
if (name.TypeArguments != null) {
is_generic = true;
count_type_params = count_current_type_params = name.TypeArguments.Count;
}
if (parent != null)
count_type_params += parent.count_type_params;
}
///
/// Adds the member to defined_names table. It tests for duplications and enclosing name conflicts
///
protected bool AddToContainer (MemberCore symbol, string fullname, string basename)
{
if (basename == Basename && !(this is Interface)) {
if (symbol is TypeParameter)
Report.Error (694, "Type parameter `{0}' has same name as " +
"containing type or method", basename);
else {
Report.SymbolRelatedToPreviousError (this);
Report.Error (542, "'{0}': member names cannot be the same as their " +
"enclosing type", symbol.Location, symbol.GetSignatureForError ());
}
return false;
}
MemberCore mc = (MemberCore)defined_names [fullname];
if (mc == null) {
defined_names.Add (fullname, symbol);
return true;
}
if (symbol.MarkForDuplicationCheck () && mc.MarkForDuplicationCheck ())
return true;
if (symbol is TypeParameter)
Report.Error (692, symbol.Location, "Duplicate type parameter `{0}'", basename);
else {
Report.SymbolRelatedToPreviousError (mc);
Report.Error (102, symbol.Location,
"The type '{0}' already contains a definition for '{1}'",
GetSignatureForError (), basename);
}
return false;
}
public void RecordDecl ()
{
if ((NamespaceEntry != null) && (Parent == RootContext.Tree.Types))
NamespaceEntry.DefineName (MemberName.Basename, this);
}
///
/// Returns the MemberCore associated with a given name in the declaration
/// space. It doesn't return method based symbols !!
///
///
public MemberCore GetDefinition (string name)
{
return (MemberCore)defined_names [name];
}
bool in_transit = false;
///
/// This function is used to catch recursive definitions
/// in declarations.
///
public bool InTransit {
get {
return in_transit;
}
set {
in_transit = value;
}
}
//
// root_types contains all the types. All TopLevel types
// hence have a parent that points to `root_types', that is
// why there is a non-obvious test down here.
//
public bool IsTopLevel {
get {
if (Parent != null){
if (Parent.Parent == null)
return true;
}
return false;
}
}
public virtual void CloseType ()
{
if ((caching_flags & Flags.CloseTypeCreated) == 0){
try {
TypeBuilder.CreateType ();
} catch {
//
// The try/catch is needed because
// nested enumerations fail to load when they
// are defined.
//
// Even if this is the right order (enumerations
// declared after types).
//
// Note that this still creates the type and
// it is possible to save it
}
caching_flags |= Flags.CloseTypeCreated;
}
}
///
/// Should be overriten by the appropriate declaration space
///
public abstract TypeBuilder DefineType ();
///
/// Define all members, but don't apply any attributes or do anything which may
/// access not-yet-defined classes. This method also creates the MemberCache.
///
public abstract bool DefineMembers (TypeContainer parent);
//
// Whether this is an `unsafe context'
//
public bool UnsafeContext {
get {
if ((ModFlags & Modifiers.UNSAFE) != 0)
return true;
if (Parent != null)
return Parent.UnsafeContext;
return false;
}
}
public static string MakeFQN (string nsn, string name)
{
if (nsn == "")
return name;
return String.Concat (nsn, ".", name);
}
EmitContext type_resolve_ec;
protected EmitContext TypeResolveEmitContext {
get {
if (type_resolve_ec == null) {
// FIXME: I think this should really be one of:
//
// a. type_resolve_ec = Parent.EmitContext;
// b. type_resolve_ec = new EmitContext (Parent, Parent, loc, null, null, ModFlags, false);
//
// However, if Parent == RootContext.Tree.Types, its NamespaceEntry will be null.
//
type_resolve_ec = new EmitContext (Parent, this, Location.Null, null, null, ModFlags, false);
}
return type_resolve_ec;
}
}
//
// Resolves the expression `e' for a type, and will recursively define
// types. This should only be used for resolving base types.
//
public TypeExpr ResolveBaseTypeExpr (Expression e, bool silent, Location loc)
{
TypeResolveEmitContext.loc = loc;
TypeResolveEmitContext.ContainerType = TypeBuilder;
if (this is GenericMethod)
TypeResolveEmitContext.ContainerType = Parent.TypeBuilder;
else
TypeResolveEmitContext.ContainerType = TypeBuilder;
return e.ResolveAsTypeTerminal (TypeResolveEmitContext);
}
public bool CheckAccessLevel (Type check_type)
{
TypeBuilder tb;
if ((this is GenericMethod) || (this is Iterator))
tb = Parent.TypeBuilder;
else
tb = TypeBuilder;
if (check_type.IsGenericInstance)
check_type = check_type.GetGenericTypeDefinition ();
if (check_type == tb)
return true;
if (TypeBuilder == null)
// FIXME: TypeBuilder will be null when invoked by Class.GetNormalBases().
// However, this is invoked again later -- so safe to return true.
// May also be null when resolving top-level attributes.
return true;
if (check_type.IsGenericParameter)
return true; // FIXME
TypeAttributes check_attr = check_type.Attributes & TypeAttributes.VisibilityMask;
//
// Broken Microsoft runtime, return public for arrays, no matter what
// the accessibility is for their underlying class, and they return
// NonPublic visibility for pointers
//
if (check_type.IsArray || check_type.IsPointer)
return CheckAccessLevel (TypeManager.GetElementType (check_type));
switch (check_attr){
case TypeAttributes.Public:
return true;
case TypeAttributes.NotPublic:
if (TypeBuilder == null)
// FIXME: TypeBuilder will be null when invoked by Class.GetNormalBases().
// However, this is invoked again later -- so safe to return true.
// May also be null when resolving top-level attributes.
return true;
//
// This test should probably use the declaringtype.
//
return check_type.Assembly == TypeBuilder.Assembly;
case TypeAttributes.NestedPublic:
return true;
case TypeAttributes.NestedPrivate:
return NestedAccessible (tb, check_type);
case TypeAttributes.NestedFamily:
//
// Only accessible to methods in current type or any subtypes
//
return FamilyAccessible (tb, check_type);
case TypeAttributes.NestedFamANDAssem:
return (check_type.Assembly == tb.Assembly) &&
FamilyAccessible (tb, check_type);
case TypeAttributes.NestedFamORAssem:
return (check_type.Assembly == tb.Assembly) ||
FamilyAccessible (tb, check_type);
case TypeAttributes.NestedAssembly:
return check_type.Assembly == tb.Assembly;
}
Console.WriteLine ("HERE: " + check_attr);
return false;
}
protected bool NestedAccessible (Type tb, Type check_type)
{
Type declaring = check_type.DeclaringType;
return TypeBuilder == declaring ||
TypeManager.IsNestedChildOf (TypeBuilder, declaring);
}
protected bool FamilyAccessible (Type tb, Type check_type)
{
Type declaring = check_type.DeclaringType;
if (tb == declaring || TypeManager.IsFamilyAccessible (tb, declaring))
return true;
return NestedAccessible (tb, check_type);
}
// Access level of a type.
const int X = 1;
enum AccessLevel { // Each column represents `is this scope larger or equal to Blah scope'
// Public Assembly Protected
Protected = (0 << 0) | (0 << 1) | (X << 2),
Public = (X << 0) | (X << 1) | (X << 2),
Private = (0 << 0) | (0 << 1) | (0 << 2),
Internal = (0 << 0) | (X << 1) | (0 << 2),
ProtectedOrInternal = (0 << 0) | (X << 1) | (X << 2),
}
static AccessLevel GetAccessLevelFromModifiers (int flags)
{
if ((flags & Modifiers.INTERNAL) != 0) {
if ((flags & Modifiers.PROTECTED) != 0)
return AccessLevel.ProtectedOrInternal;
else
return AccessLevel.Internal;
} else if ((flags & Modifiers.PROTECTED) != 0)
return AccessLevel.Protected;
else if ((flags & Modifiers.PRIVATE) != 0)
return AccessLevel.Private;
else
return AccessLevel.Public;
}
// What is the effective access level of this?
// TODO: Cache this?
AccessLevel EffectiveAccessLevel {
get {
AccessLevel myAccess = GetAccessLevelFromModifiers (ModFlags);
if (!IsTopLevel && (Parent != null))
return myAccess & Parent.EffectiveAccessLevel;
return myAccess;
}
}
// Return the access level for type `t'
static AccessLevel TypeEffectiveAccessLevel (Type t)
{
if (t.IsPublic)
return AccessLevel.Public;
if (t.IsNestedPrivate)
return AccessLevel.Private;
if (t.IsNotPublic)
return AccessLevel.Internal;
// By now, it must be nested
AccessLevel parentLevel = TypeEffectiveAccessLevel (t.DeclaringType);
if (t.IsNestedPublic)
return parentLevel;
if (t.IsNestedAssembly)
return parentLevel & AccessLevel.Internal;
if (t.IsNestedFamily)
return parentLevel & AccessLevel.Protected;
if (t.IsNestedFamORAssem)
return parentLevel & AccessLevel.ProtectedOrInternal;
if (t.IsNestedFamANDAssem)
throw new NotImplementedException ("NestedFamANDAssem not implemented, cant make this kind of type from c# anyways");
// nested private is taken care of
throw new Exception ("I give up, what are you?");
}
//
// This answers `is the type P, as accessible as a member M which has the
// accessability @flags which is declared as a nested member of the type T, this declspace'
//
public bool AsAccessible (Type p, int flags)
{
if (p.IsGenericParameter)
return true; // FIXME
//
// 1) if M is private, its accessability is the same as this declspace.
// we already know that P is accessible to T before this method, so we
// may return true.
//
if ((flags & Modifiers.PRIVATE) != 0)
return true;
while (p.IsArray || p.IsPointer || p.IsByRef)
p = TypeManager.GetElementType (p);
AccessLevel pAccess = TypeEffectiveAccessLevel (p);
AccessLevel mAccess = this.EffectiveAccessLevel &
GetAccessLevelFromModifiers (flags);
// for every place from which we can access M, we must
// be able to access P as well. So, we want
// For every bit in M and P, M_i -> P_1 == true
// or, ~ (M -> P) == 0 <-> ~ ( ~M | P) == 0
return ~ (~ mAccess | pAccess) == 0;
}
public static void Error_AmbiguousTypeReference (Location loc, string name, string t1, string t2)
{
Report.Error (104, loc,
"`{0}' is an ambiguous reference ({1} or {2})",
name, t1, t2);
}
//
// Return the nested type with name @name. Ensures that the nested type
// is defined if necessary. Do _not_ use this when you have a MemberCache handy.
//
public virtual Type FindNestedType (string name)
{
return null;
}
private Type LookupNestedTypeInHierarchy (string name)
{
// if the member cache has been created, lets use it.
// the member cache is MUCH faster.
if (MemberCache != null)
return MemberCache.FindNestedType (name);
// no member cache. Do it the hard way -- reflection
Type t = null;
for (Type current_type = TypeBuilder;
current_type != null && current_type != TypeManager.object_type;
current_type = current_type.BaseType) {
if (current_type is TypeBuilder) {
DeclSpace decl = this;
if (current_type != TypeBuilder)
decl = TypeManager.LookupDeclSpace (current_type);
t = decl.FindNestedType (name);
} else {
t = TypeManager.LookupTypeDirect (current_type.FullName + "+" + name);
}
if (t != null && CheckAccessLevel (t))
return t;
}
return null;
}
//
// Public function used to locate types, this can only
// be used after the ResolveTree function has been invoked.
//
// Set 'ignore_cs0104' to true if you want to ignore cs0104 errors.
//
// Returns: Type or null if they type can not be found.
//
public FullNamedExpression LookupType (string name, Location loc, bool ignore_cs0104)
{
if (this is PartialContainer)
throw new InternalErrorException ("Should not get here");
if (Cache.Contains (name))
return (FullNamedExpression) Cache [name];
FullNamedExpression e;
Type t = LookupNestedTypeInHierarchy (name);
if (t != null)
e = new TypeExpression (t, Location.Null);
else if (Parent != null && Parent != RootContext.Tree.Types)
e = Parent.LookupType (name, loc, ignore_cs0104);
else
e = NamespaceEntry.LookupNamespaceOrType (this, name, loc, ignore_cs0104);
Cache [name] = e;
return e;
}
///
/// This function is broken and not what you're looking for. It should only
/// be used while the type is still being created since it doesn't use the cache
/// and relies on the filter doing the member name check.
///
public abstract MemberList FindMembers (MemberTypes mt, BindingFlags bf,
MemberFilter filter, object criteria);
///
/// If we have a MemberCache, return it. This property may return null if the
/// class doesn't have a member cache or while it's still being created.
///
public abstract MemberCache MemberCache {
get;
}
public override void ApplyAttributeBuilder (Attribute a, CustomAttributeBuilder cb)
{
TypeBuilder.SetCustomAttribute (cb);
}
///
/// Goes through class hierarchy and get value of first CLSCompliantAttribute that found.
/// If no is attribute exists then return assembly CLSCompliantAttribute.
///
public bool GetClsCompliantAttributeValue ()
{
if ((caching_flags & Flags.HasCompliantAttribute_Undetected) == 0)
return (caching_flags & Flags.ClsCompliantAttributeTrue) != 0;
caching_flags &= ~Flags.HasCompliantAttribute_Undetected;
if (OptAttributes != null) {
Attribute cls_attribute = OptAttributes.Search (TypeManager.cls_compliant_attribute_type, ec);
if (cls_attribute != null) {
caching_flags |= Flags.HasClsCompliantAttribute;
if (cls_attribute.GetClsCompliantAttributeValue (ec)) {
caching_flags |= Flags.ClsCompliantAttributeTrue;
return true;
}
return false;
}
}
if (Parent == null) {
if (CodeGen.Assembly.IsClsCompliant) {
caching_flags |= Flags.ClsCompliantAttributeTrue;
return true;
}
return false;
}
if (Parent.GetClsCompliantAttributeValue ()) {
caching_flags |= Flags.ClsCompliantAttributeTrue;
return true;
}
return false;
}
//
// Extensions for generics
//
TypeParameter[] type_params;
TypeParameter[] type_param_list;
protected string GetInstantiationName ()
{
StringBuilder sb = new StringBuilder (Name);
sb.Append ("<");
for (int i = 0; i < type_param_list.Length; i++) {
if (i > 0)
sb.Append (",");
sb.Append (type_param_list [i].Name);
}
sb.Append (">");
return sb.ToString ();
}
bool check_type_parameter (ArrayList list, int start, string name)
{
for (int i = 0; i < start; i++) {
TypeParameter param = (TypeParameter) list [i];
if (param.Name != name)
continue;
if (RootContext.WarningLevel >= 3)
Report.Warning (
693, Location,
"Type parameter `{0}' has same name " +
"as type parameter from outer type `{1}'",
name, Parent.GetInstantiationName ());
return false;
}
return true;
}
TypeParameter[] initialize_type_params ()
{
if (type_param_list != null)
return type_param_list;
DeclSpace the_parent = Parent;
if (this is GenericMethod)
the_parent = null;
int start = 0;
TypeParameter[] parent_params = null;
if ((the_parent != null) && the_parent.IsGeneric) {
parent_params = the_parent.initialize_type_params ();
start = parent_params != null ? parent_params.Length : 0;
}
ArrayList list = new ArrayList ();
if (parent_params != null)
list.AddRange (parent_params);
int count = type_params != null ? type_params.Length : 0;
for (int i = 0; i < count; i++) {
TypeParameter param = type_params [i];
check_type_parameter (list, start, param.Name);
list.Add (param);
}
type_param_list = new TypeParameter [list.Count];
list.CopyTo (type_param_list, 0);
return type_param_list;
}
public virtual void SetParameterInfo (ArrayList constraints_list)
{
if (!is_generic) {
if (constraints_list != null) {
Report.Error (
80, Location, "Contraints are not allowed " +
"on non-generic declarations");
}
return;
}
string[] names = MemberName.TypeArguments.GetDeclarations ();
type_params = new TypeParameter [names.Length];
//
// Register all the names
//
for (int i = 0; i < type_params.Length; i++) {
string name = names [i];
Constraints constraints = null;
if (constraints_list != null) {
foreach (Constraints constraint in constraints_list) {
if (constraint.TypeParameter == name) {
constraints = constraint;
break;
}
}
}
type_params [i] = new TypeParameter (Parent, name, constraints, Location);
string full_name = Name + "." + name;
AddToContainer (type_params [i], full_name, name);
}
}
public TypeParameter[] TypeParameters {
get {
if (!IsGeneric)
throw new InvalidOperationException ();
if (type_param_list == null)
initialize_type_params ();
return type_param_list;
}
}
protected TypeParameter[] CurrentTypeParameters {
get {
if (!IsGeneric)
throw new InvalidOperationException ();
if (type_params != null)
return type_params;
else
return new TypeParameter [0];
}
}
public int CountTypeParameters {
get {
return count_type_params;
}
}
public int CountCurrentTypeParameters {
get {
return count_current_type_params;
}
}
public TypeParameterExpr LookupGeneric (string name, Location loc)
{
if (!IsGeneric)
return null;
foreach (TypeParameter type_param in CurrentTypeParameters) {
if (type_param.Name != name)
continue;
return new TypeParameterExpr (type_param, loc);
}
if (Parent != null)
return Parent.LookupGeneric (name, loc);
return null;
}
bool IAlias.IsType {
get { return true; }
}
string IAlias.Name {
get { return Name; }
}
TypeExpr IAlias.ResolveAsType (EmitContext ec)
{
if (TypeBuilder == null)
throw new InvalidOperationException ();
if (CurrentType != null)
return new TypeExpression (CurrentType, Location);
else
return new TypeExpression (TypeBuilder, Location);
}
public override string[] ValidAttributeTargets {
get {
return attribute_targets;
}
}
}
///
/// This is a readonly list of MemberInfo's.
///
public class MemberList : IList {
public readonly IList List;
int count;
///
/// Create a new MemberList from the given IList.
///
public MemberList (IList list)
{
if (list != null)
this.List = list;
else
this.List = new ArrayList ();
count = List.Count;
}
///
/// Concatenate the ILists `first' and `second' to a new MemberList.
///
public MemberList (IList first, IList second)
{
ArrayList list = new ArrayList ();
list.AddRange (first);
list.AddRange (second);
count = list.Count;
List = list;
}
public static readonly MemberList Empty = new MemberList (new ArrayList ());
///
/// Cast the MemberList into a MemberInfo[] array.
///
///
/// This is an expensive operation, only use it if it's really necessary.
///
public static explicit operator MemberInfo [] (MemberList list)
{
Timer.StartTimer (TimerType.MiscTimer);
MemberInfo [] result = new MemberInfo [list.Count];
list.CopyTo (result, 0);
Timer.StopTimer (TimerType.MiscTimer);
return result;
}
// ICollection
public int Count {
get {
return count;
}
}
public bool IsSynchronized {
get {
return List.IsSynchronized;
}
}
public object SyncRoot {
get {
return List.SyncRoot;
}
}
public void CopyTo (Array array, int index)
{
List.CopyTo (array, index);
}
// IEnumerable
public IEnumerator GetEnumerator ()
{
return List.GetEnumerator ();
}
// IList
public bool IsFixedSize {
get {
return true;
}
}
public bool IsReadOnly {
get {
return true;
}
}
object IList.this [int index] {
get {
return List [index];
}
set {
throw new NotSupportedException ();
}
}
// FIXME: try to find out whether we can avoid the cast in this indexer.
public MemberInfo this [int index] {
get {
return (MemberInfo) List [index];
}
}
public int Add (object value)
{
throw new NotSupportedException ();
}
public void Clear ()
{
throw new NotSupportedException ();
}
public bool Contains (object value)
{
return List.Contains (value);
}
public int IndexOf (object value)
{
return List.IndexOf (value);
}
public void Insert (int index, object value)
{
throw new NotSupportedException ();
}
public void Remove (object value)
{
throw new NotSupportedException ();
}
public void RemoveAt (int index)
{
throw new NotSupportedException ();
}
}
///
/// This interface is used to get all members of a class when creating the
/// member cache. It must be implemented by all DeclSpace derivatives which
/// want to support the member cache and by TypeHandle to get caching of
/// non-dynamic types.
///
public interface IMemberContainer {
///
/// The name of the IMemberContainer. This is only used for
/// debugging purposes.
///
string Name {
get;
}
///
/// The type of this IMemberContainer.
///
Type Type {
get;
}
///
/// Returns the IMemberContainer of the base class or null if this
/// is an interface or TypeManger.object_type.
/// This is used when creating the member cache for a class to get all
/// members from the base class.
///
MemberCache BaseCache {
get;
}
///
/// Whether this is an interface.
///
bool IsInterface {
get;
}
///
/// Returns all members of this class with the corresponding MemberTypes
/// and BindingFlags.
///
///
/// When implementing this method, make sure not to return any inherited
/// members and check the MemberTypes and BindingFlags properly.
/// Unfortunately, System.Reflection is lame and doesn't provide a way to
/// get the BindingFlags (static/non-static,public/non-public) in the
/// MemberInfo class, but the cache needs this information. That's why
/// this method is called multiple times with different BindingFlags.
///
MemberList GetMembers (MemberTypes mt, BindingFlags bf);
///
/// Return the container's member cache.
///
MemberCache MemberCache {
get;
}
}
///
/// The MemberCache is used by dynamic and non-dynamic types to speed up
/// member lookups. It has a member name based hash table; it maps each member
/// name to a list of CacheEntry objects. Each CacheEntry contains a MemberInfo
/// and the BindingFlags that were initially used to get it. The cache contains
/// all members of the current class and all inherited members. If this cache is
/// for an interface types, it also contains all inherited members.
///
/// There are two ways to get a MemberCache:
/// * if this is a dynamic type, lookup the corresponding DeclSpace and then
/// use the DeclSpace.MemberCache property.
/// * if this not a dynamic type, call TypeHandle.GetTypeHandle() to get a
/// TypeHandle instance for the type and then use TypeHandle.MemberCache.
///
public class MemberCache {
public readonly IMemberContainer Container;
protected Hashtable member_hash;
protected Hashtable method_hash;
///
/// Create a new MemberCache for the given IMemberContainer `container'.
///
public MemberCache (IMemberContainer container)
{
this.Container = container;
Timer.IncrementCounter (CounterType.MemberCache);
Timer.StartTimer (TimerType.CacheInit);
// If we have a base class (we have a base class unless we're
// TypeManager.object_type), we deep-copy its MemberCache here.
if (Container.BaseCache != null)
member_hash = SetupCache (Container.BaseCache);
else
member_hash = new Hashtable ();
// If this is neither a dynamic type nor an interface, create a special
// method cache with all declared and inherited methods.
Type type = container.Type;
if (!(type is TypeBuilder) && !type.IsInterface &&
// !(type.IsGenericInstance && (type.GetGenericTypeDefinition () is TypeBuilder)) &&
!type.IsGenericInstance &&
(Container.BaseCache == null || Container.BaseCache.method_hash != null)) {
method_hash = new Hashtable ();
AddMethods (type);
}
// Add all members from the current class.
AddMembers (Container);
Timer.StopTimer (TimerType.CacheInit);
}
public MemberCache (Type[] ifaces)
{
//
// The members of this cache all belong to other caches.
// So, 'Container' will not be used.
//
this.Container = null;
member_hash = new Hashtable ();
if (ifaces == null)
return;
foreach (Type itype in ifaces)
AddCacheContents (TypeManager.LookupMemberCache (itype));
}
///
/// Bootstrap this member cache by doing a deep-copy of our base.
///
Hashtable SetupCache (MemberCache base_class)
{
Hashtable hash = new Hashtable ();
if (base_class == null)
return hash;
IDictionaryEnumerator it = base_class.member_hash.GetEnumerator ();
while (it.MoveNext ()) {
hash [it.Key] = ((ArrayList) it.Value).Clone ();
}
return hash;
}
void ClearDeclaredOnly (Hashtable hash)
{
IDictionaryEnumerator it = hash.GetEnumerator ();
while (it.MoveNext ()) {
foreach (CacheEntry ce in (ArrayList) it.Value)
ce.EntryType &= ~EntryType.Declared;
}
}
///
/// Add the contents of `cache' to the member_hash.
///
void AddCacheContents (MemberCache cache)
{
IDictionaryEnumerator it = cache.member_hash.GetEnumerator ();
while (it.MoveNext ()) {
ArrayList list = (ArrayList) member_hash [it.Key];
if (list == null)
member_hash [it.Key] = list = new ArrayList ();
ArrayList entries = (ArrayList) it.Value;
for (int i = entries.Count-1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) entries [i];
if (entry.Container != cache.Container)
break;
list.Add (entry);
}
}
}
///
/// Add all members from class `container' to the cache.
///
void AddMembers (IMemberContainer container)
{
// We need to call AddMembers() with a single member type at a time
// to get the member type part of CacheEntry.EntryType right.
if (!container.IsInterface) {
AddMembers (MemberTypes.Constructor, container);
AddMembers (MemberTypes.Field, container);
}
AddMembers (MemberTypes.Method, container);
AddMembers (MemberTypes.Property, container);
AddMembers (MemberTypes.Event, container);
// Nested types are returned by both Static and Instance searches.
AddMembers (MemberTypes.NestedType,
BindingFlags.Static | BindingFlags.Public, container);
AddMembers (MemberTypes.NestedType,
BindingFlags.Static | BindingFlags.NonPublic, container);
}
void AddMembers (MemberTypes mt, IMemberContainer container)
{
AddMembers (mt, BindingFlags.Static | BindingFlags.Public, container);
AddMembers (mt, BindingFlags.Static | BindingFlags.NonPublic, container);
AddMembers (mt, BindingFlags.Instance | BindingFlags.Public, container);
AddMembers (mt, BindingFlags.Instance | BindingFlags.NonPublic, container);
}
///
/// Add all members from class `container' with the requested MemberTypes and
/// BindingFlags to the cache. This method is called multiple times with different
/// MemberTypes and BindingFlags.
///
void AddMembers (MemberTypes mt, BindingFlags bf, IMemberContainer container)
{
MemberList members = container.GetMembers (mt, bf);
foreach (MemberInfo member in members) {
string name = member.Name;
int pos = name.IndexOf ('<');
if (pos > 0)
name = name.Substring (0, pos);
// We use a name-based hash table of ArrayList's.
ArrayList list = (ArrayList) member_hash [name];
if (list == null) {
list = new ArrayList ();
member_hash.Add (name, list);
}
// When this method is called for the current class, the list will
// already contain all inherited members from our base classes.
// We cannot add new members in front of the list since this'd be an
// expensive operation, that's why the list is sorted in reverse order
// (ie. members from the current class are coming last).
list.Add (new CacheEntry (container, member, mt, bf));
}
}
///
/// Add all declared and inherited methods from class `type' to the method cache.
///
void AddMethods (Type type)
{
AddMethods (BindingFlags.Static | BindingFlags.Public |
BindingFlags.FlattenHierarchy, type);
AddMethods (BindingFlags.Static | BindingFlags.NonPublic |
BindingFlags.FlattenHierarchy, type);
AddMethods (BindingFlags.Instance | BindingFlags.Public, type);
AddMethods (BindingFlags.Instance | BindingFlags.NonPublic, type);
}
void AddMethods (BindingFlags bf, Type type)
{
//
// Consider the case:
//
// class X { public virtual int f() {} }
// class Y : X {}
//
// When processing 'Y', the method_cache will already have a copy of 'f',
// with ReflectedType == X. However, we want to ensure that its ReflectedType == Y
//
MethodBase [] members = type.GetMethods (bf);
Array.Reverse (members);
foreach (MethodBase member in members) {
string name = member.Name;
// We use a name-based hash table of ArrayList's.
ArrayList list = (ArrayList) method_hash [name];
if (list == null) {
list = new ArrayList ();
method_hash.Add (name, list);
}
if (member.IsVirtual &&
(member.Attributes & MethodAttributes.NewSlot) == 0) {
MethodInfo base_method = ((MethodInfo) member).GetBaseDefinition ();
if (base_method == member) {
//
// Both mcs and CSC 1.1 seem to emit a somewhat broken
// ...Invoke () function for delegates: it's missing a 'newslot'.
// CSC 2.0 emits a 'newslot' for a delegate's Invoke.
//
if (member.Name != "Invoke" ||
!TypeManager.IsDelegateType (type)) {
Report.SymbolRelatedToPreviousError (base_method);
Report.Warning (-28,
"{0} contains a method '{1}' that is marked " +
" virtual, but doesn't appear to have a slot." +
" The method may be ignored during overload resolution",
type, base_method);
}
goto skip;
}
for (;;) {
list.Add (new CacheEntry (null, base_method, MemberTypes.Method, bf));
if ((base_method.Attributes & MethodAttributes.NewSlot) != 0)
break;
//
// Shouldn't get here. Mono appears to be buggy.
//
MethodInfo new_base_method = base_method.GetBaseDefinition ();
if (new_base_method == base_method) {
Report.SymbolRelatedToPreviousError (base_method);
Report.Warning (-28,
"{0} contains a method '{1}' that is marked " +
" virtual, but doesn't appear to have a slot." +
" The method may be ignored during overload resolution",
type, base_method);
}
base_method = new_base_method;
}
}
skip:
// Unfortunately, the elements returned by Type.GetMethods() aren't
// sorted so we need to do this check for every member.
BindingFlags new_bf = bf;
if (member.DeclaringType == type)
new_bf |= BindingFlags.DeclaredOnly;
list.Add (new CacheEntry (Container, member, MemberTypes.Method, new_bf));
}
}
///
/// Compute and return a appropriate `EntryType' magic number for the given
/// MemberTypes and BindingFlags.
///
protected static EntryType GetEntryType (MemberTypes mt, BindingFlags bf)
{
EntryType type = EntryType.None;
if ((mt & MemberTypes.Constructor) != 0)
type |= EntryType.Constructor;
if ((mt & MemberTypes.Event) != 0)
type |= EntryType.Event;
if ((mt & MemberTypes.Field) != 0)
type |= EntryType.Field;
if ((mt & MemberTypes.Method) != 0)
type |= EntryType.Method;
if ((mt & MemberTypes.Property) != 0)
type |= EntryType.Property;
// Nested types are returned by static and instance searches.
if ((mt & MemberTypes.NestedType) != 0)
type |= EntryType.NestedType | EntryType.Static | EntryType.Instance;
if ((bf & BindingFlags.Instance) != 0)
type |= EntryType.Instance;
if ((bf & BindingFlags.Static) != 0)
type |= EntryType.Static;
if ((bf & BindingFlags.Public) != 0)
type |= EntryType.Public;
if ((bf & BindingFlags.NonPublic) != 0)
type |= EntryType.NonPublic;
if ((bf & BindingFlags.DeclaredOnly) != 0)
type |= EntryType.Declared;
return type;
}
///
/// The `MemberTypes' enumeration type is a [Flags] type which means that it may
/// denote multiple member types. Returns true if the given flags value denotes a
/// single member types.
///
public static bool IsSingleMemberType (MemberTypes mt)
{
switch (mt) {
case MemberTypes.Constructor:
case MemberTypes.Event:
case MemberTypes.Field:
case MemberTypes.Method:
case MemberTypes.Property:
case MemberTypes.NestedType:
return true;
default:
return false;
}
}
///
/// We encode the MemberTypes and BindingFlags of each members in a "magic"
/// number to speed up the searching process.
///
[Flags]
protected enum EntryType {
None = 0x000,
Instance = 0x001,
Static = 0x002,
MaskStatic = Instance|Static,
Public = 0x004,
NonPublic = 0x008,
MaskProtection = Public|NonPublic,
Declared = 0x010,
Constructor = 0x020,
Event = 0x040,
Field = 0x080,
Method = 0x100,
Property = 0x200,
NestedType = 0x400,
MaskType = Constructor|Event|Field|Method|Property|NestedType
}
protected class CacheEntry {
public readonly IMemberContainer Container;
public EntryType EntryType;
public MemberInfo Member;
public CacheEntry (IMemberContainer container, MemberInfo member,
MemberTypes mt, BindingFlags bf)
{
this.Container = container;
this.Member = member;
this.EntryType = GetEntryType (mt, bf);
}
public override string ToString ()
{
return String.Format ("CacheEntry ({0}:{1}:{2})", Container.Name,
EntryType, Member);
}
}
///
/// This is called each time we're walking up one level in the class hierarchy
/// and checks whether we can abort the search since we've already found what
/// we were looking for.
///
protected bool DoneSearching (ArrayList list)
{
//
// We've found exactly one member in the current class and it's not
// a method or constructor.
//
if (list.Count == 1 && !(list [0] is MethodBase))
return true;
//
// Multiple properties: we query those just to find out the indexer
// name
//
if ((list.Count > 0) && (list [0] is PropertyInfo))
return true;
return false;
}
///
/// Looks up members with name `name'. If you provide an optional
/// filter function, it'll only be called with members matching the
/// requested member name.
///
/// This method will try to use the cache to do the lookup if possible.
///
/// Unlike other FindMembers implementations, this method will always
/// check all inherited members - even when called on an interface type.
///
/// If you know that you're only looking for methods, you should use
/// MemberTypes.Method alone since this speeds up the lookup a bit.
/// When doing a method-only search, it'll try to use a special method
/// cache (unless it's a dynamic type or an interface) and the returned
/// MemberInfo's will have the correct ReflectedType for inherited methods.
/// The lookup process will automatically restart itself in method-only
/// search mode if it discovers that it's about to return methods.
///
ArrayList global = new ArrayList ();
bool using_global = false;
static MemberInfo [] emptyMemberInfo = new MemberInfo [0];
public MemberInfo [] FindMembers (MemberTypes mt, BindingFlags bf, string name,
MemberFilter filter, object criteria)
{
if (using_global)
throw new Exception ();
bool declared_only = (bf & BindingFlags.DeclaredOnly) != 0;
bool method_search = mt == MemberTypes.Method;
// If we have a method cache and we aren't already doing a method-only search,
// then we restart a method search if the first match is a method.
bool do_method_search = !method_search && (method_hash != null);
ArrayList applicable;
// If this is a method-only search, we try to use the method cache if
// possible; a lookup in the method cache will return a MemberInfo with
// the correct ReflectedType for inherited methods.
if (method_search && (method_hash != null))
applicable = (ArrayList) method_hash [name];
else
applicable = (ArrayList) member_hash [name];
if (applicable == null)
return emptyMemberInfo;
//
// 32 slots gives 53 rss/54 size
// 2/4 slots gives 55 rss
//
// Strange: from 25,000 calls, only 1,800
// are above 2. Why does this impact it?
//
global.Clear ();
using_global = true;
Timer.StartTimer (TimerType.CachedLookup);
EntryType type = GetEntryType (mt, bf);
IMemberContainer current = Container;
// `applicable' is a list of all members with the given member name `name'
// in the current class and all its base classes. The list is sorted in
// reverse order due to the way how the cache is initialy created (to speed
// things up, we're doing a deep-copy of our base).
for (int i = applicable.Count-1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) applicable [i];
// This happens each time we're walking one level up in the class
// hierarchy. If we're doing a DeclaredOnly search, we must abort
// the first time this happens (this may already happen in the first
// iteration of this loop if there are no members with the name we're
// looking for in the current class).
if (entry.Container != current) {
if (declared_only || DoneSearching (global))
break;
current = entry.Container;
}
// Is the member of the correct type ?
if ((entry.EntryType & type & EntryType.MaskType) == 0)
continue;
// Is the member static/non-static ?
if ((entry.EntryType & type & EntryType.MaskStatic) == 0)
continue;
// Apply the filter to it.
if (filter (entry.Member, criteria)) {
if ((entry.EntryType & EntryType.MaskType) != EntryType.Method)
do_method_search = false;
global.Add (entry.Member);
}
}
Timer.StopTimer (TimerType.CachedLookup);
// If we have a method cache and we aren't already doing a method-only
// search, we restart in method-only search mode if the first match is
// a method. This ensures that we return a MemberInfo with the correct
// ReflectedType for inherited methods.
if (do_method_search && (global.Count > 0)){
using_global = false;
return FindMembers (MemberTypes.Method, bf, name, filter, criteria);
}
using_global = false;
MemberInfo [] copy = new MemberInfo [global.Count];
global.CopyTo (copy);
return copy;
}
// find the nested type @name in @this.
public Type FindNestedType (string name)
{
ArrayList applicable = (ArrayList) member_hash [name];
if (applicable == null)
return null;
for (int i = applicable.Count-1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) applicable [i];
if ((entry.EntryType & EntryType.NestedType & EntryType.MaskType) != 0)
return (Type) entry.Member;
}
return null;
}
//
// This finds the method or property for us to override. invocationType is the type where
// the override is going to be declared, name is the name of the method/property, and
// paramTypes is the parameters, if any to the method or property
//
// Because the MemberCache holds members from this class and all the base classes,
// we can avoid tons of reflection stuff.
//
public MemberInfo FindMemberToOverride (Type invocationType, string name, Type [] paramTypes, bool is_property)
{
ArrayList applicable;
if (method_hash != null && !is_property)
applicable = (ArrayList) method_hash [name];
else
applicable = (ArrayList) member_hash [name];
if (applicable == null)
return null;
//
// Walk the chain of methods, starting from the top.
//
for (int i = applicable.Count - 1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) applicable [i];
if ((entry.EntryType & (is_property ? (EntryType.Property | EntryType.Field) : EntryType.Method)) == 0)
continue;
PropertyInfo pi = null;
MethodInfo mi = null;
FieldInfo fi = null;
Type [] cmpAttrs = null;
if (is_property) {
if ((entry.EntryType & EntryType.Field) != 0) {
fi = (FieldInfo)entry.Member;
// TODO: For this case we ignore member type
//fb = TypeManager.GetField (fi);
//cmpAttrs = new Type[] { fb.MemberType };
} else {
pi = (PropertyInfo) entry.Member;
cmpAttrs = TypeManager.GetArgumentTypes (pi);
}
} else {
mi = (MethodInfo) entry.Member;
cmpAttrs = TypeManager.GetArgumentTypes (mi);
}
if (fi != null) {
// TODO: Almost duplicate !
// Check visibility
switch (fi.Attributes & FieldAttributes.FieldAccessMask) {
case FieldAttributes.Private:
//
// A private method is Ok if we are a nested subtype.
// The spec actually is not very clear about this, see bug 52458.
//
if (invocationType != entry.Container.Type &
TypeManager.IsNestedChildOf (invocationType, entry.Container.Type))
continue;
break;
case FieldAttributes.FamANDAssem:
case FieldAttributes.Assembly:
//
// Check for assembly methods
//
if (mi.DeclaringType.Assembly != CodeGen.Assembly.Builder)
continue;
break;
}
return entry.Member;
}
//
// Check the arguments
//
if (cmpAttrs.Length != paramTypes.Length)
continue;
for (int j = cmpAttrs.Length - 1; j >= 0; j --) {
if (!TypeManager.IsEqual (paramTypes [j], cmpAttrs [j]))
goto next;
}
//
// get one of the methods because this has the visibility info.
//
if (is_property) {
mi = pi.GetGetMethod (true);
if (mi == null)
mi = pi.GetSetMethod (true);
}
//
// Check visibility
//
switch (mi.Attributes & MethodAttributes.MemberAccessMask) {
case MethodAttributes.Private:
//
// A private method is Ok if we are a nested subtype.
// The spec actually is not very clear about this, see bug 52458.
//
if (invocationType.Equals (entry.Container.Type) ||
TypeManager.IsNestedChildOf (invocationType, entry.Container.Type))
return entry.Member;
break;
case MethodAttributes.FamANDAssem:
case MethodAttributes.Assembly:
//
// Check for assembly methods
//
if (mi.DeclaringType.Assembly == CodeGen.Assembly.Builder)
return entry.Member;
break;
default:
//
// A protected method is ok, because we are overriding.
// public is always ok.
//
return entry.Member;
}
next:
;
}
return null;
}
///
/// The method is looking for conflict with inherited symbols (errors CS0108, CS0109).
/// We handle two cases. The first is for types without parameters (events, field, properties).
/// The second are methods, indexers and this is why ignore_complex_types is here.
/// The latest param is temporary hack. See DoDefineMembers method for more info.
///
public MemberInfo FindMemberWithSameName (string name, bool ignore_complex_types, MemberInfo ignore_member)
{
ArrayList applicable = null;
if (method_hash != null)
applicable = (ArrayList) method_hash [name];
if (applicable != null) {
for (int i = applicable.Count - 1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) applicable [i];
if ((entry.EntryType & EntryType.Public) != 0)
return entry.Member;
}
}
if (member_hash == null)
return null;
applicable = (ArrayList) member_hash [name];
if (applicable != null) {
for (int i = applicable.Count - 1; i >= 0; i--) {
CacheEntry entry = (CacheEntry) applicable [i];
if ((entry.EntryType & EntryType.Public) != 0 & entry.Member != ignore_member) {
if (ignore_complex_types) {
if ((entry.EntryType & EntryType.Method) != 0)
continue;
// Does exist easier way how to detect indexer ?
if ((entry.EntryType & EntryType.Property) != 0) {
Type[] arg_types = TypeManager.GetArgumentTypes ((PropertyInfo)entry.Member);
if (arg_types.Length > 0)
continue;
}
}
return entry.Member;
}
}
}
return null;
}
Hashtable locase_table;
///
/// Builds low-case table for CLS Compliance test
///
public Hashtable GetPublicMembers ()
{
if (locase_table != null)
return locase_table;
locase_table = new Hashtable ();
foreach (DictionaryEntry entry in member_hash) {
ArrayList members = (ArrayList)entry.Value;
for (int ii = 0; ii < members.Count; ++ii) {
CacheEntry member_entry = (CacheEntry) members [ii];
if ((member_entry.EntryType & EntryType.Public) == 0)
continue;
// TODO: Does anyone know easier way how to detect that member is internal ?
switch (member_entry.EntryType & EntryType.MaskType) {
case EntryType.Constructor:
continue;
case EntryType.Field:
if ((((FieldInfo)member_entry.Member).Attributes & (FieldAttributes.Assembly | FieldAttributes.Public)) == FieldAttributes.Assembly)
continue;
break;
case EntryType.Method:
if ((((MethodInfo)member_entry.Member).Attributes & (MethodAttributes.Assembly | MethodAttributes.Public)) == MethodAttributes.Assembly)
continue;
break;
case EntryType.Property:
PropertyInfo pi = (PropertyInfo)member_entry.Member;
if (pi.GetSetMethod () == null && pi.GetGetMethod () == null)
continue;
break;
case EntryType.Event:
EventInfo ei = (EventInfo)member_entry.Member;
MethodInfo mi = ei.GetAddMethod ();
if ((mi.Attributes & (MethodAttributes.Assembly | MethodAttributes.Public)) == MethodAttributes.Assembly)
continue;
break;
}
string lcase = ((string)entry.Key).ToLower (System.Globalization.CultureInfo.InvariantCulture);
locase_table [lcase] = member_entry.Member;
break;
}
}
return locase_table;
}
public Hashtable Members {
get {
return member_hash;
}
}
///
/// Cls compliance check whether methods or constructors parameters differing only in ref or out, or in array rank
///
public void VerifyClsParameterConflict (ArrayList al, MethodCore method, MemberInfo this_builder)
{
EntryType tested_type = (method is Constructor ? EntryType.Constructor : EntryType.Method) | EntryType.Public;
for (int i = 0; i < al.Count; ++i) {
MemberCache.CacheEntry entry = (MemberCache.CacheEntry) al [i];
// skip itself
if (entry.Member == this_builder)
continue;
if ((entry.EntryType & tested_type) != tested_type)
continue;
MethodBase method_to_compare = (MethodBase)entry.Member;
if (AttributeTester.AreOverloadedMethodParamsClsCompliant (method.ParameterTypes, TypeManager.GetArgumentTypes (method_to_compare)))
continue;
IMethodData md = TypeManager.GetMethod (method_to_compare);
// TODO: now we are ignoring CLSCompliance(false) on method from other assembly which is buggy.
// However it is exactly what csc does.
if (md != null && !md.IsClsCompliaceRequired (method.Parent))
continue;
Report.SymbolRelatedToPreviousError (entry.Member);
Report.Error (3006, method.Location, "Overloaded method '{0}' differing only in ref or out, or in array rank, is not CLS-compliant", method.GetSignatureForError ());
}
}
}
}