// (C) 2001 Ximian, Inc (http://www.ximian.com)
//
//
-#define CACHE
+
+//
+// We will eventually remove the SIMPLE_SPEEDUP, and should never change
+// the behavior of the compilation. This can be removed if we rework
+// the code to get a list of namespaces available.
+//
+#define SIMPLE_SPEEDUP
using System;
+using System.IO;
using System.Globalization;
using System.Collections;
using System.Reflection;
static public Type methodimpl_attr_type;
static public Type marshal_as_attr_type;
static public Type param_array_type;
+ static public Type guid_attr_type;
static public Type void_ptr_type;
static public Type indexer_name_type;
+ static public Type exception_type;
static public object obsolete_attribute_type;
static public object conditional_attribute_type;
+ //
+ // An empty array of types
+ //
static public Type [] NoTypes;
+
+ //
+ // Expressions representing the internal types. Used during declaration
+ // definition.
+ //
+ static public Expression system_object_expr, system_string_expr;
+ static public Expression system_boolean_expr, system_decimal_expr;
+ static public Expression system_single_expr, system_double_expr;
+ static public Expression system_sbyte_expr, system_byte_expr;
+ static public Expression system_int16_expr, system_uint16_expr;
+ static public Expression system_int32_expr, system_uint32_expr;
+ static public Expression system_int64_expr, system_uint64_expr;
+ static public Expression system_char_expr, system_void_expr;
+ static public Expression system_asynccallback_expr;
+ static public Expression system_iasyncresult_expr;
+
//
// This is only used when compiling corlib
//
// These methods are called by code generated by the compiler
//
static public MethodInfo string_concat_string_string;
+ static public MethodInfo string_concat_string_string_string;
+ static public MethodInfo string_concat_string_string_string_string;
static public MethodInfo string_concat_object_object;
static public MethodInfo string_isinterneted_string;
static public MethodInfo system_type_get_type_from_handle;
// </remarks>
static ArrayList user_types;
- // <remarks>
- // Keeps a mapping between TypeBuilders and their TypeContainers
- // </remarks>
- static PtrHashtable builder_to_container;
+ static PtrHashtable builder_to_declspace;
// <remarks>
// Tracks the interfaces implemented by typebuilders. We only
// </remarks>
static Hashtable method_arguments;
+ // <remarks>
+ // Maps PropertyBuilder to a Type array that contains
+ // the arguments to the indexer
+ // </remarks>
+ static Hashtable indexer_arguments;
+
// <remarks>
// Maybe `method_arguments' should be replaced and only
// method_internal_params should be kept?
// <remarks>
static Hashtable method_internal_params;
- static PtrHashtable builder_to_interface;
-
- // <remarks>
- // Keeps track of delegate types
- // </remarks>
-
- static Hashtable builder_to_delegate;
-
// <remarks>
- // Keeps track of enum types
+ // Keeps track of attribute types
// </remarks>
- static Hashtable builder_to_enum;
+ static Hashtable builder_to_attr;
// <remarks>
- // Keeps track of attribute types
+ // Keeps track of methods
// </remarks>
- static Hashtable builder_to_attr;
+ static Hashtable builder_to_method;
struct Signature {
public string name;
// A delegate that points to the filter above.
static MemberFilter signature_filter;
+ //
+ // These are expressions that represent some of the internal data types, used
+ // elsewhere
+ //
+ static void InitExpressionTypes ()
+ {
+ system_object_expr = new TypeLookupExpression ("System.Object");
+ system_string_expr = new TypeLookupExpression ("System.String");
+ system_boolean_expr = new TypeLookupExpression ("System.Boolean");
+ system_decimal_expr = new TypeLookupExpression ("System.Decimal");
+ system_single_expr = new TypeLookupExpression ("System.Single");
+ system_double_expr = new TypeLookupExpression ("System.Double");
+ system_sbyte_expr = new TypeLookupExpression ("System.SByte");
+ system_byte_expr = new TypeLookupExpression ("System.Byte");
+ system_int16_expr = new TypeLookupExpression ("System.Int16");
+ system_uint16_expr = new TypeLookupExpression ("System.UInt16");
+ system_int32_expr = new TypeLookupExpression ("System.Int32");
+ system_uint32_expr = new TypeLookupExpression ("System.UInt32");
+ system_int64_expr = new TypeLookupExpression ("System.Int64");
+ system_uint64_expr = new TypeLookupExpression ("System.UInt64");
+ system_char_expr = new TypeLookupExpression ("System.Char");
+ system_void_expr = new TypeLookupExpression ("System.Void");
+ system_asynccallback_expr = new TypeLookupExpression ("System.AsyncCallback");
+ system_iasyncresult_expr = new TypeLookupExpression ("System.IAsyncResult");
+ }
+
static TypeManager ()
{
assemblies = new Assembly [0];
types = new Hashtable ();
typecontainers = new Hashtable ();
- builder_to_interface = new PtrHashtable ();
- builder_to_delegate = new PtrHashtable ();
- builder_to_enum = new PtrHashtable ();
+ builder_to_declspace = new PtrHashtable ();
builder_to_attr = new PtrHashtable ();
+ builder_to_method = new PtrHashtable ();
method_arguments = new PtrHashtable ();
method_internal_params = new PtrHashtable ();
- builder_to_container = new PtrHashtable ();
+ indexer_arguments = new PtrHashtable ();
builder_to_ifaces = new PtrHashtable ();
NoTypes = new Type [0];
signature_filter = new MemberFilter (SignatureFilter);
+ InitExpressionTypes ();
}
public static void AddUserType (string name, TypeBuilder t, Type [] ifaces)
types.Add (name, t);
} catch {
Type prev = (Type) types [name];
- TypeContainer tc = (TypeContainer) builder_to_container [prev];
+ TypeContainer tc = builder_to_declspace [prev] as TypeContainer;
if (tc != null){
//
return;
}
- tc = (TypeContainer) builder_to_container [t];
+ tc = builder_to_declspace [t] as TypeContainer;
Report.Warning (
1595, "The type `" + name + "' is defined in an existing assembly;"+
public static void AddUserType (string name, TypeBuilder t, TypeContainer tc, Type [] ifaces)
{
- builder_to_container.Add (t, tc);
+ builder_to_declspace.Add (t, tc);
typecontainers.Add (name, tc);
AddUserType (name, t, ifaces);
}
public static void AddDelegateType (string name, TypeBuilder t, Delegate del)
{
types.Add (name, t);
- builder_to_delegate.Add (t, del);
+ builder_to_declspace.Add (t, del);
}
public static void AddEnumType (string name, TypeBuilder t, Enum en)
{
types.Add (name, t);
- builder_to_enum.Add (t, en);
+ builder_to_declspace.Add (t, en);
}
public static void AddUserInterface (string name, TypeBuilder t, Interface i, Type [] ifaces)
{
AddUserType (name, t, ifaces);
- builder_to_interface.Add (t, i);
+ builder_to_declspace.Add (t, i);
+ }
+
+ public static void AddMethod (MethodBuilder builder, MethodData method)
+ {
+ builder_to_method.Add (builder, method);
}
public static void RegisterAttrType (Type t, TypeContainer tc)
{
builder_to_attr.Add (t, tc);
}
-
+
/// <summary>
/// Returns the TypeContainer whose Type is `t' or null if there is no
/// TypeContainer for `t' (ie, the Type comes from a library)
/// </summary>
public static TypeContainer LookupTypeContainer (Type t)
{
- return (TypeContainer) builder_to_container [t];
+ return builder_to_declspace [t] as TypeContainer;
+ }
+
+ public static IMemberContainer LookupMemberContainer (Type t)
+ {
+ if (t is TypeBuilder) {
+ IMemberContainer container = builder_to_declspace [t] as IMemberContainer;
+ if (container != null)
+ return container;
+ }
+
+ return TypeHandle.GetTypeHandle (t);
}
public static Interface LookupInterface (Type t)
{
- return (Interface) builder_to_interface [t];
+ return builder_to_declspace [t] as Interface;
}
public static Delegate LookupDelegate (Type t)
{
- return (Delegate) builder_to_delegate [t];
+ return builder_to_declspace [t] as Delegate;
}
public static Enum LookupEnum (Type t)
{
- return (Enum) builder_to_enum [t];
+ return builder_to_declspace [t] as Enum;
}
public static TypeContainer LookupAttr (Type t)
modules = n;
}
+ //
+ // Low-level lookup, cache-less
+ //
+ static Type LookupTypeReflection (string name)
+ {
+ Type t;
+
+ foreach (Assembly a in assemblies){
+ t = a.GetType (name);
+ if (t != null)
+ return t;
+ }
+
+ foreach (ModuleBuilder mb in modules) {
+ t = mb.GetType (name);
+ if (t != null){
+ return t;
+ }
+ }
+ return null;
+ }
+
+ static Hashtable negative_hits = new Hashtable ();
+
+ //
+ // This function is used when you want to avoid the lookups, and want to go
+ // directly to the source. This will use the cache.
+ //
+ // Notice that bypassing the cache is bad, because on Microsoft.NET runtime
+ // GetType ("DynamicType[]") != GetType ("DynamicType[]"), and there is no
+ // way to test things other than doing a fullname compare
+ //
+ public static Type LookupTypeDirect (string name)
+ {
+ Type t = (Type) types [name];
+ if (t != null)
+ return t;
+
+ t = LookupTypeReflection (name);
+ if (t == null)
+ return null;
+
+ types [name] = t;
+ return t;
+ }
+
/// <summary>
- /// Returns the Type associated with @name
+ /// Returns the Type associated with @name, takes care of the fact that
+ /// reflection expects nested types to be separated from the main type
+ /// with a "+" instead of a "."
/// </summary>
public static Type LookupType (string name)
{
if (t != null)
return t;
- foreach (Assembly a in assemblies){
- t = a.GetType (name);
- if (t != null){
- types [name] = t;
+#if SIMPLE_SPEEDUP
+ if (negative_hits.Contains (name))
+ return null;
+#endif
+
+ //
+ // Optimization: ComposedCast will work with an existing type, and might already have the
+ // full name of the type, so the full system lookup can probably be avoided.
+ //
+
+ string [] elements = name.Split ('.');
+ int count = elements.Length;
+ for (int n = 1; n <= count; n++){
+ string top_level_type = String.Join (".", elements, 0, n);
+
+ t = (Type) types [top_level_type];
+ if (t == null){
+ t = LookupTypeReflection (top_level_type);
+ if (t == null)
+ continue;
+ }
+
+ if (count == n){
+ types [name] = t;
return t;
+ }
+
+ //
+ // We know that System.Object does not have children, and since its the parent of
+ // all the objects, it always gets probbed for inner classes.
+ //
+ if (top_level_type == "System.Object")
+ return null;
+
+ string newt = top_level_type + "+" + String.Join ("+", elements, n, count - n);
+ t = LookupTypeDirect (newt);
+ if (t != null)
+ types [newt] = t;
+ return t;
+ }
+
+#if SIMPLE_SPEEDUP
+ negative_hits [name] = true;
+#endif
+ return null;
+ }
+
+ static Hashtable assemblies_namespaces = new Hashtable ();
+
+ //
+ // Returns a list of all namespaces in the assemblies and types loaded.
+ //
+ static Hashtable ExtractAssemblyNamespaces ()
+ {
+ foreach (Assembly a in assemblies){
+ foreach (Type t in a.GetTypes ()){
+ string ns = t.Namespace;
+
+ if (assemblies_namespaces.Contains (ns))
+ continue;
+ assemblies_namespaces [ns] = ns;
}
}
- foreach (ModuleBuilder mb in modules) {
- t = mb.GetType (name);
- if (t != null) {
- types [name] = t;
- return t;
+ return assemblies_namespaces;
+ }
+
+ static Hashtable AddModuleNamespaces (Hashtable h)
+ {
+ foreach (ModuleBuilder mb in modules){
+ foreach (Type t in mb.GetTypes ()){
+ string ns = t.Namespace;
+
+ if (h.Contains (ns))
+ continue;
+ h [ns] = ns;
}
}
+ return h;
+ }
+
+
+ /// <summary>
+ /// Returns the list of namespaces that are active for this executable
+ /// </summary>
+ public static Hashtable GetAssemblyNamespaces (string executable_name)
+ {
+ string cache_name = executable_name + ".nsc";
+ Hashtable cached_namespaces = LoadCache (cache_name);
+
+ if (cached_namespaces != null)
+ assemblies_namespaces = cached_namespaces;
+ else {
+ Console.WriteLine ("rebuilding namespace cache");
+ assemblies_namespaces = ExtractAssemblyNamespaces ();
+ SaveCache (cache_name);
+ }
+
+ return assemblies_namespaces;
+ }
+
+ public static Hashtable GetNamespaces ()
+ {
+ if (assemblies_namespaces == null)
+ assemblies_namespaces = ExtractAssemblyNamespaces ();
+
+ Hashtable nh = (Hashtable) assemblies_namespaces.Clone ();
+
+ return AddModuleNamespaces (nh);
+ }
+
+ //
+ // Loads the namespace cache for the given executable name
+ //
+ static Hashtable LoadCache (string cache_file)
+ {
+ if (!File.Exists (cache_file)){
+ Console.WriteLine ("Cache not found");
+ return null;
+ }
+
+ Hashtable cached_module_list, cached_namespaces;
+ try {
+ using (FileStream fs = File.OpenRead (cache_file)){
+ StreamReader reader = new StreamReader (fs);
+
+ int assembly_count = Int32.Parse (reader.ReadLine ());
+
+ if (assembly_count != assemblies.Length){
+ Console.WriteLine ("Assembly missmatch ({0}, {1})", assembly_count, assemblies.Length);
+ return null;
+ }
+
+ int namespace_count = Int32.Parse (reader.ReadLine ());
+
+ cached_module_list = new Hashtable (assembly_count);
+ for (int i = 0; i < assembly_count; i++)
+ cached_module_list [reader.ReadLine ()] = true;
+
+ cached_namespaces = new Hashtable (namespace_count);
+ for (int i = 0; i < namespace_count; i++){
+ string s = reader.ReadLine ();
+ cached_namespaces [s] = s;
+ }
+ }
+
+ //
+ // Now, check that the cache is still valid
+ //
+
+ foreach (Assembly a in assemblies)
+ if (cached_module_list [a.CodeBase] == null){
+ Console.WriteLine ("assembly not found in cache: " + a.CodeBase);
+ return null;
+ }
+
+ return cached_namespaces;
+ } catch {
+ }
return null;
}
+ static void SaveCache (string cache_file)
+ {
+ try {
+ using (FileStream fs = File.OpenWrite (cache_file)){
+ StreamWriter writer = new StreamWriter (fs);
+
+ writer.WriteLine (assemblies.Length);
+ writer.WriteLine (assemblies_namespaces.Count);
+
+ foreach (Assembly a in assemblies)
+ writer.WriteLine (a.CodeBase);
+
+ foreach (DictionaryEntry de in assemblies_namespaces){
+ writer.WriteLine ((string) de.Key);
+ }
+
+ writer.Flush ();
+ fs.Flush ();
+ }
+ } catch (Exception e) {
+ Console.WriteLine ("Failed: " + e);
+ }
+ }
+
+ public static void GetAllTypes ()
+ {
+ Hashtable namespaces = new Hashtable ();
+
+ foreach (Assembly a in assemblies){
+ foreach (Type t in a.GetTypes ()){
+ }
+ }
+
+ foreach (ModuleBuilder mb in modules){
+ foreach (Type t in mb.GetTypes ()){
+ }
+ }
+ }
+
+
/// <summary>
/// Returns the C# name of a type if possible, or the full type name otherwise
/// </summary>
/// </summary>
static MethodInfo GetMethod (Type t, string name, Type [] args)
{
- MemberInfo [] mi;
+ MemberList list;
Signature sig;
sig.name = name;
sig.args = args;
- mi = FindMembers (
- t, MemberTypes.Method,
- instance_and_static | BindingFlags.Public, signature_filter, sig);
- if (mi == null || mi.Length == 0 || !(mi [0] is MethodInfo)){
+ list = FindMembers (t, MemberTypes.Method, instance_and_static | BindingFlags.Public,
+ signature_filter, sig);
+ if (list.Count == 0) {
+ Report.Error (-19, "Can not find the core function `" + name + "'");
+ return null;
+ }
+
+ MethodInfo mi = list [0] as MethodInfo;
+ if (mi == null) {
Report.Error (-19, "Can not find the core function `" + name + "'");
return null;
}
- return (MethodInfo) mi [0];
+ return mi;
}
/// <summary>
/// </summary>
static ConstructorInfo GetConstructor (Type t, Type [] args)
{
- MemberInfo [] mi;
+ MemberList list;
Signature sig;
sig.name = ".ctor";
sig.args = args;
- mi = FindMembers (t, MemberTypes.Constructor,
- instance_and_static | BindingFlags.Public | BindingFlags.DeclaredOnly, signature_filter, sig);
- if (mi == null || mi.Length == 0 || !(mi [0] is ConstructorInfo)){
+ list = FindMembers (t, MemberTypes.Constructor,
+ instance_and_static | BindingFlags.Public | BindingFlags.DeclaredOnly,
+ signature_filter, sig);
+ if (list.Count == 0){
+ Report.Error (-19, "Can not find the core constructor for type `" + t.Name + "'");
+ return null;
+ }
+
+ ConstructorInfo ci = list [0] as ConstructorInfo;
+ if (ci == null){
Report.Error (-19, "Can not find the core constructor for type `" + t.Name + "'");
return null;
}
- return (ConstructorInfo) mi [0];
+ return ci;
}
public static void InitEnumUnderlyingTypes ()
marshal_as_attr_type = CoreLookupType ("System.Runtime.InteropServices.MarshalAsAttribute");
param_array_type = CoreLookupType ("System.ParamArrayAttribute");
+ //
+ // Temporary while people upgrade their corlibs
+ //
+ //
+ // Change from LookupType to CoreLookupType before release
+ //
+ guid_attr_type = LookupType ("System.Runtime.InteropServices.GuidAttribute");
+
unverifiable_code_type= CoreLookupType ("System.Security.UnverifiableCodeAttribute");
void_ptr_type = CoreLookupType ("System.Void*");
indexer_name_type = CoreLookupType ("System.Runtime.CompilerServices.IndexerNameAttribute");
+ exception_type = CoreLookupType ("System.Exception");
+
//
// Attribute types
//
system_void_array_copyto_array_int = GetMethod (
system_array_type, "CopyTo", system_array_int_arg);
- Type [] system_type_type_arg = { system_type_type, system_type_type };
+ Type [] system_type_type_arg = { system_type_type, system_type_type, system_type_type };
+
+ try {
system_void_set_corlib_type_builders = GetMethod (
system_assemblybuilder_type, "SetCorlibTypeBuilders",
system_type_type_arg);
- object[] args = new object [2];
+ object[] args = new object [3];
args [0] = object_type;
args [1] = value_type;
+ args [2] = enum_type;
system_void_set_corlib_type_builders.Invoke (CodeGen.AssemblyBuilder, args);
+ } catch {
+ Console.WriteLine ("Corlib compilation is not supported in Microsoft.NET due to bugs in it");
+ }
}
}
Type [] string_string = { string_type, string_type };
string_concat_string_string = GetMethod (
string_type, "Concat", string_string);
+ Type [] string_string_string = { string_type, string_type, string_type };
+ string_concat_string_string_string = GetMethod (
+ string_type, "Concat", string_string_string);
+ Type [] string_string_string_string = { string_type, string_type, string_type, string_type };
+ string_concat_string_string_string_string = GetMethod (
+ string_type, "Concat", string_string_string_string);
Type [] object_object = { object_type, object_type };
string_concat_object_object = GetMethod (
const BindingFlags instance_and_static = BindingFlags.Static | BindingFlags.Instance;
- //
- // FIXME: This can be optimized easily. speedup by having a single builder mapping
- //
- public static MemberInfo [] FindMembers (Type t, MemberTypes mt, BindingFlags bf,
- MemberFilter filter, object criteria)
+ static Hashtable type_hash = new Hashtable ();
+
+ /// <remarks>
+ /// This is the "old", non-cache based FindMembers() function. We cannot use
+ /// the cache here because there is no member name argument.
+ /// </remarks>
+ public static MemberList FindMembers (Type t, MemberTypes mt, BindingFlags bf,
+ MemberFilter filter, object criteria)
{
+ DeclSpace decl = (DeclSpace) builder_to_declspace [t];
+
+ //
+ // `builder_to_declspace' contains all dynamic types.
+ //
+ if (decl != null) {
+ MemberList list;
+ Timer.StartTimer (TimerType.FindMembers);
+ list = decl.FindMembers (mt, bf, filter, criteria);
+ Timer.StopTimer (TimerType.FindMembers);
+ return list;
+ }
+
//
// We have to take care of arrays specially, because GetType on
// a TypeBuilder array will return a Type, not a TypeBuilder,
// and we can not call FindMembers on this type.
//
if (t.IsSubclassOf (TypeManager.array_type))
- return TypeManager.array_type.FindMembers (mt, bf, filter, criteria);
-
- if (!(t is TypeBuilder)){
- //
- // Since FindMembers will not lookup both static and instance
- // members, we emulate this behaviour here.
- //
- if ((bf & instance_and_static) == instance_and_static){
- MemberInfo [] i_members = t.FindMembers (
- mt, bf & ~BindingFlags.Static, filter, criteria);
-
- int i_len = i_members.Length;
- if (i_len == 1){
- MemberInfo one = i_members [0];
-
- //
- // If any of these are present, we are done!
- //
- if ((one is Type) || (one is EventInfo) || (one is FieldInfo))
- return i_members;
- }
+ return new MemberList (TypeManager.array_type.FindMembers (mt, bf, filter, criteria));
+
+ //
+ // Since FindMembers will not lookup both static and instance
+ // members, we emulate this behaviour here.
+ //
+ if ((bf & instance_and_static) == instance_and_static){
+ MemberInfo [] i_members = t.FindMembers (
+ mt, bf & ~BindingFlags.Static, filter, criteria);
+
+ int i_len = i_members.Length;
+ if (i_len == 1){
+ MemberInfo one = i_members [0];
+
+ //
+ // If any of these are present, we are done!
+ //
+ if ((one is Type) || (one is EventInfo) || (one is FieldInfo))
+ return new MemberList (i_members);
+ }
- MemberInfo [] s_members = t.FindMembers (
- mt, bf & ~BindingFlags.Instance, filter, criteria);
-
- int s_len = s_members.Length;
- if (i_len > 0 || s_len > 0){
- MemberInfo [] both = new MemberInfo [i_len + s_len];
-
- i_members.CopyTo (both, 0);
- s_members.CopyTo (both, i_len);
-
- return both;
- } else {
- if (i_len > 0)
- return i_members;
- else
- return s_members;
- }
+ MemberInfo [] s_members = t.FindMembers (
+ mt, bf & ~BindingFlags.Instance, filter, criteria);
+
+ int s_len = s_members.Length;
+ if (i_len > 0 || s_len > 0)
+ return new MemberList (i_members, s_members);
+ else {
+ if (i_len > 0)
+ return new MemberList (i_members);
+ else
+ return new MemberList (s_members);
}
- return t.FindMembers (mt, bf, filter, criteria);
}
+ return new MemberList (t.FindMembers (mt, bf, filter, criteria));
+ }
+
+
+ /// <summary>
+ /// This method is only called from within MemberLookup. It tries to use the member
+ /// cache if possible and falls back to the normal FindMembers if not. The `used_cache'
+ /// flag tells the caller whether we used the cache or not. If we used the cache, then
+ /// our return value will already contain all inherited members and the caller don't need
+ /// to check base classes and interfaces anymore.
+ /// </summary>
+ private static MemberList MemberLookup_FindMembers (Type t, MemberTypes mt, BindingFlags bf,
+ string name, out bool used_cache)
+ {
//
- // FIXME: We should not have builder_to_blah everywhere,
- // we should just have a builder_to_findmemberizable
- // and have them implement a new ICanFindMembers interface
+ // We have to take care of arrays specially, because GetType on
+ // a TypeBuilder array will return a Type, not a TypeBuilder,
+ // and we can not call FindMembers on this type.
//
- Enum e = (Enum) builder_to_enum [t];
+ if (t.IsSubclassOf (TypeManager.array_type)) {
+ used_cache = true;
+ return TypeHandle.ArrayType.MemberCache.FindMembers (
+ mt, bf, name, FilterWithClosure_delegate, null);
+ }
- if (e != null)
- return e.FindMembers (mt, bf, filter, criteria);
-
- Delegate del = (Delegate) builder_to_delegate [t];
+ //
+ // If this is a dynamic type, it's always in the `builder_to_declspace' hash table
+ // and we can ask the DeclSpace for the MemberCache.
+ //
+ if (t is TypeBuilder) {
+ DeclSpace decl = (DeclSpace) builder_to_declspace [t];
+ MemberCache cache = decl.MemberCache;
- if (del != null)
- return del.FindMembers (mt, bf, filter, criteria);
+ //
+ // If this DeclSpace has a MemberCache, use it.
+ //
- Interface iface = (Interface) builder_to_interface [t];
+ if (cache != null) {
+ used_cache = true;
+ return cache.FindMembers (
+ mt, bf, name, FilterWithClosure_delegate, null);
+ }
- if (iface != null)
- return iface.FindMembers (mt, bf, filter, criteria);
-
- TypeContainer tc = (TypeContainer) builder_to_container [t];
+ // If there is no MemberCache, we need to use the "normal" FindMembers.
- if (tc != null)
- return tc.FindMembers (mt, bf, filter, criteria);
+ MemberList list;
+ Timer.StartTimer (TimerType.FindMembers);
+ list = decl.FindMembers (mt, bf | BindingFlags.DeclaredOnly,
+ FilterWithClosure_delegate, name);
+ Timer.StopTimer (TimerType.FindMembers);
+ used_cache = false;
+ return list;
+ }
- return null;
+ //
+ // This call will always succeed. There is exactly one TypeHandle instance per
+ // type, TypeHandle.GetTypeHandle() will either return it or create a new one
+ // if it didn't already exist.
+ //
+ TypeHandle handle = TypeHandle.GetTypeHandle (t);
+
+ used_cache = true;
+ return handle.MemberCache.FindMembers (mt, bf, name, FilterWithClosure_delegate, null);
}
public static bool IsBuiltinType (Type t)
if (t == object_type || t == string_type || t == int32_type || t == uint32_type ||
t == int64_type || t == uint64_type || t == float_type || t == double_type ||
t == char_type || t == short_type || t == decimal_type || t == bool_type ||
+ t == sbyte_type || t == byte_type || t == ushort_type || t == void_type)
+ return true;
+ else
+ return false;
+ }
+
+ //
+ // This is like IsBuiltinType, but lacks decimal_type, we should also clean up
+ // the pieces in the code where we use IsBuiltinType and special case decimal_type.
+ //
+ public static bool IsCLRType (Type t)
+ {
+ if (t == object_type || t == int32_type || t == uint32_type ||
+ t == int64_type || t == uint64_type || t == float_type || t == double_type ||
+ t == char_type || t == short_type || t == bool_type ||
t == sbyte_type || t == byte_type || t == ushort_type)
return true;
else
else
return false;
}
+
+ //
+ // Whether a type is unmanaged. This is used by the unsafe code (25.2)
+ //
+ public static bool IsUnmanagedType (Type t)
+ {
+ if (IsBuiltinType (t) && t != TypeManager.string_type)
+ return true;
+
+ if (IsEnumType (t))
+ return true;
+
+ if (t.IsPointer)
+ return true;
+
+ if (IsValueType (t)){
+ if (t is TypeBuilder){
+ TypeContainer tc = LookupTypeContainer (t);
+
+ foreach (Field f in tc.Fields){
+ if (f.FieldBuilder.IsStatic)
+ continue;
+ if (!IsUnmanagedType (f.FieldBuilder.FieldType))
+ return false;
+ }
+ } else {
+ FieldInfo [] fields = t.GetFields ();
+
+ foreach (FieldInfo f in fields){
+ if (f.IsStatic)
+ continue;
+ if (!IsUnmanagedType (f.FieldType))
+ return false;
+ }
+ }
+ return true;
+ }
+
+ return false;
+ }
+
+ public static bool IsValueType (Type t)
+ {
+ if (t.IsSubclassOf (TypeManager.value_type))
+ return true;
+ else
+ return false;
+ }
public static bool IsInterfaceType (Type t)
{
- Interface iface = (Interface) builder_to_interface [t];
+ Interface iface = builder_to_declspace [t] as Interface;
if (iface != null)
return true;
return false;
}
+ //
+ // Checks whether `type' is a subclass or nested child of `parent'.
+ //
+ public static bool IsSubclassOrNestedChildOf (Type type, Type parent)
+ {
+ do {
+ if ((type == parent) || type.IsSubclassOf (parent))
+ return true;
+
+ // Handle nested types.
+ type = type.DeclaringType;
+ } while (type != null);
+
+ return false;
+ }
+
+ //
+ // Checks whether `type' is a nested child of `parent'.
+ //
+ public static bool IsNestedChildOf (Type type, Type parent)
+ {
+ if ((type == parent) || type.IsSubclassOf (parent))
+ return false;
+ else
+ return IsSubclassOrNestedChildOf (type, parent);
+ }
+
/// <summary>
/// Returns the User Defined Types
/// </summary>
}
}
+ static Hashtable attr_to_allowmult;
+
+ public static void RegisterAttributeAllowMultiple (Type attr_type, bool allow)
+ {
+ if (attr_to_allowmult == null)
+ attr_to_allowmult = new PtrHashtable ();
+
+ if (attr_to_allowmult.Contains (attr_type))
+ return;
+
+ attr_to_allowmult.Add (attr_type, allow);
+
+ }
+
+ public static bool AreMultipleAllowed (Type attr_type)
+ {
+ if (!(attr_type is TypeBuilder)) {
+ System.Attribute [] attrs = System.Attribute.GetCustomAttributes (attr_type);
+
+ foreach (System.Attribute tmp in attrs)
+ if (tmp is AttributeUsageAttribute)
+ return ((AttributeUsageAttribute) tmp).AllowMultiple;
+
+ return false;
+ }
+
+ if (attr_to_allowmult == null)
+ return false;
+
+ return (bool) attr_to_allowmult [attr_type];
+ }
+
static Hashtable builder_to_constant;
public static void RegisterConstant (FieldBuilder fb, Const c)
return types;
}
}
+
+ /// <summary>
+ /// Returns the argument types for an indexer based on its PropertyInfo
+ ///
+ /// For dynamic indexers, we use the compiler provided types, for
+ /// indexers from existing assemblies we load them from GetParameters,
+ /// and insert them into the cache
+ /// </summary>
+ static public Type [] GetArgumentTypes (PropertyInfo indexer)
+ {
+ if (indexer_arguments.Contains (indexer))
+ return (Type []) indexer_arguments [indexer];
+ else if (indexer is PropertyBuilder)
+ // If we're a PropertyBuilder and not in the
+ // `indexer_arguments' hash, then we're a property and
+ // not an indexer.
+ return NoTypes;
+ else {
+ ParameterInfo [] pi = indexer.GetIndexParameters ();
+ // Property, not an indexer.
+ if (pi == null)
+ return NoTypes;
+ int c = pi.Length;
+ Type [] types = new Type [c];
+
+ for (int i = 0; i < c; i++)
+ types [i] = pi [i].ParameterType;
+
+ indexer_arguments.Add (indexer, types);
+ return types;
+ }
+ }
// <remarks>
// This is a workaround the fact that GetValue is not
return (MethodInfo) pair.Second;
} else
- return ei.GetAddMethod ();
+ return ei.GetRemoveMethod ();
}
static Hashtable priv_fields_events;
{
return (MemberInfo) priv_fields_events [ei];
}
-
+
static Hashtable properties;
static public bool RegisterProperty (PropertyBuilder pb, MethodBase get, MethodBase set)
return true;
}
-
- //
- // FIXME: we need to return the accessors depending on whether
- // they are visible or not.
- //
- static public MethodInfo [] GetAccessors (PropertyInfo pi)
- {
- MethodInfo [] ret;
-
- if (pi is PropertyBuilder){
- Pair pair = (Pair) properties [pi];
-
- ret = new MethodInfo [2];
- ret [0] = (MethodInfo) pair.First;
- ret [1] = (MethodInfo) pair.Second;
-
- return ret;
- } else {
- MethodInfo [] mi = new MethodInfo [2];
-
- //
- // Why this and not pi.GetAccessors?
- // Because sometimes index 0 is the getter
- // sometimes it is 1
- //
- mi [0] = pi.GetGetMethod (true);
- mi [1] = pi.GetSetMethod (true);
-
- return mi;
- }
- }
- static public MethodInfo GetPropertyGetter (PropertyInfo pi)
+ static public bool RegisterIndexer (PropertyBuilder pb, MethodBase get, MethodBase set, Type[] args)
{
- if (pi is PropertyBuilder){
- Pair de = (Pair) properties [pi];
-
- return (MethodInfo) de.Second;
- } else
- return pi.GetSetMethod ();
- }
+ if (!RegisterProperty (pb, get,set))
+ return false;
- static public MethodInfo GetPropertySetter (PropertyInfo pi)
- {
- if (pi is PropertyBuilder){
- Pair de = (Pair) properties [pi];
+ indexer_arguments.Add (pb, args);
- return (MethodInfo) de.First;
- } else
- return pi.GetGetMethod ();
+ return true;
}
/// <summary>
// This is a custom version of Convert.ChangeType() which works
// with the TypeBuilder defined types when compiling corlib.
- public static object ChangeType (object value, Type conversionType)
+ public static object ChangeType (object value, Type conversionType, out bool error)
{
- if (!(value is IConvertible))
- throw new ArgumentException ();
-
+ if (!(value is IConvertible)){
+ error = true;
+ return null;
+ }
+
IConvertible convertValue = (IConvertible) value;
CultureInfo ci = CultureInfo.CurrentCulture;
NumberFormatInfo provider = ci.NumberFormat;
// the system type itself. You cannot use Type.GetTypeCode()
// on such a type - it'd always return TypeCode.Object.
//
+ error = false;
if (conversionType.Equals (typeof (Boolean)))
return (object)(convertValue.ToBoolean (provider));
else if (conversionType.Equals (typeof (Byte)))
else if (conversionType.Equals (typeof (Object)))
return (object)(value);
else
- throw new InvalidCastException ();
+ error = true;
+ return null;
}
//
case TypeCode.String:
return TypeManager.string_type;
default:
+ if (t == typeof (void))
+ return TypeManager.void_type;
+ if (t == typeof (object))
+ return TypeManager.object_type;
+ if (t == typeof (System.Type))
+ return TypeManager.type_type;
return t;
}
}
/// </remarks>
public static string IndexerPropertyName (Type t)
{
-
if (t is TypeBuilder) {
- TypeContainer tc = (TypeContainer) builder_to_container [t];
+ if (t.IsInterface) {
+ Interface i = LookupInterface (t);
- //
- // FIXME: Temporary hack, until we deploy the IndexerName
- // property code (and attributes) in the interface code.
- //
- if (tc == null){
- return "Item";
+ if ((i == null) || (i.IndexerName == null))
+ return "Item";
+
+ return i.IndexerName;
+ } else {
+ TypeContainer tc = LookupTypeContainer (t);
+
+ if ((tc == null) || (tc.IndexerName == null))
+ return "Item";
+
+ return tc.IndexerName;
}
-
- return tc.IndexerName;
}
System.Attribute attr = System.Attribute.GetCustomAttribute (
}
if (i != old_count)
continue;
-
- if (!(method is MethodInfo && new_method is MethodInfo))
- return true;
-
- if (((MethodInfo) method).ReturnType == ((MethodInfo) new_method).ReturnType)
- return true;
+
+ return true;
}
return false;
}
//
// The name is assumed to be the same.
//
- public static ArrayList CopyNewMethods (ArrayList target_list, MemberInfo [] new_members)
+ public static ArrayList CopyNewMethods (ArrayList target_list, MemberList new_members)
{
if (target_list == null){
target_list = new ArrayList ();
[Flags]
public enum MethodFlags {
IsObsolete = 1,
- ShouldIgnore = 2
+ IsObsoleteError = 2,
+ ShouldIgnore = 3
}
- static public MethodFlags GetMethodFlags (MethodBase mb)
+ //
+ // Returns the TypeManager.MethodFlags for this method.
+ // This emits an error 619 / warning 618 if the method is obsolete.
+ // In the former case, TypeManager.MethodFlags.IsObsoleteError is returned.
+ //
+ static public MethodFlags GetMethodFlags (MethodBase mb, Location loc)
{
MethodFlags flags = 0;
if (mb.DeclaringType is TypeBuilder){
- //
- // FIXME: Support lookups of Obsolete and ConditionalAttribute
- // on MethodBuilders.
- //
- return 0;
+ MethodData method = (MethodData) builder_to_method [mb];
+ if (method == null) {
+ // FIXME: implement Obsolete attribute on Property,
+ // Indexer and Event.
+ return 0;
+ }
+
+ return method.GetMethodFlags (loc);
}
- object [] attrs = mb.GetCustomAttributes (false);
+ object [] attrs = mb.GetCustomAttributes (true);
foreach (object ta in attrs){
if (!(ta is System.Attribute)){
Console.WriteLine ("Unknown type in GetMethodFlags: " + ta);
}
System.Attribute a = (System.Attribute) ta;
if (a.TypeId == TypeManager.obsolete_attribute_type){
+ ObsoleteAttribute oa = (ObsoleteAttribute) a;
+
+ string method_desc = TypeManager.CSharpSignature (mb);
+
+ if (oa.IsError) {
+ Report.Error (619, loc, "Method `" + method_desc +
+ "' is obsolete: `" + oa.Message + "'");
+ return MethodFlags.IsObsoleteError;
+ } else
+ Report.Warning (618, loc, "Method `" + method_desc +
+ "' is obsolete: `" + oa.Message + "'");
+
flags |= MethodFlags.IsObsolete;
+
continue;
}
//
static Type closure_invocation_type;
static Type closure_queried_type;
+ static Type closure_qualifier_type;
//
// The assembly that defines the type is that is calling us
// fields.
//
- if (m.Name != closure_name)
+ if ((filter_criteria != null) && (m.Name != (string) filter_criteria))
return false;
+ if (((closure_qualifier_type == null) || (closure_qualifier_type == closure_invocation_type)) &&
+ (m.DeclaringType == closure_invocation_type))
+ return true;
+
//
// Ugly: we need to find out the type of `m', and depending
// on this, tell whether we accept or not
MethodAttributes ma = mb.Attributes & MethodAttributes.MemberAccessMask;
if (ma == MethodAttributes.Private)
- return closure_private_ok;
+ return closure_private_ok || (closure_invocation_type == m.DeclaringType);
//
// FamAndAssem requires that we not only derivate, but we are on the
return false;
}
- // FamORAssem, Family and Public:
+ // Assembly and FamORAssem succeed if we're in the same assembly.
+ if ((ma == MethodAttributes.Assembly) || (ma == MethodAttributes.FamORAssem)){
+ if (closure_invocation_assembly == mb.DeclaringType.Assembly)
+ return true;
+ }
+
+ // We already know that we aren't in the same assembly.
+ if (ma == MethodAttributes.Assembly)
+ return false;
+
+ // Family and FamANDAssem require that we derive.
+ if ((ma == MethodAttributes.Family) || (ma == MethodAttributes.FamANDAssem)){
+ if (closure_invocation_type == null)
+ return false;
+
+ if (!IsSubclassOrNestedChildOf (closure_invocation_type, mb.DeclaringType))
+ return false;
+
+ // Although a derived class can access protected members of its base class
+ // it cannot do so through an instance of the base class (CS1540).
+ if (!mb.IsStatic && (closure_invocation_type != closure_qualifier_type) &&
+ (closure_qualifier_type != null) &&
+ closure_invocation_type.IsSubclassOf (closure_qualifier_type))
+ return false;
+
+ return true;
+ }
+
+ // Public.
return true;
}
FieldAttributes fa = fi.Attributes & FieldAttributes.FieldAccessMask;
if (fa == FieldAttributes.Private)
- return closure_private_ok;
+ return closure_private_ok || (closure_invocation_type == m.DeclaringType);
//
// FamAndAssem requires that we not only derivate, but we are on the
if (closure_invocation_assembly != fi.DeclaringType.Assembly)
return false;
}
- // FamORAssem, Family and Public:
+
+ // Assembly and FamORAssem succeed if we're in the same assembly.
+ if ((fa == FieldAttributes.Assembly) || (fa == FieldAttributes.FamORAssem)){
+ if (closure_invocation_assembly == fi.DeclaringType.Assembly)
+ return true;
+ }
+
+ // We already know that we aren't in the same assembly.
+ if (fa == FieldAttributes.Assembly)
+ return false;
+
+ // Family and FamANDAssem require that we derive.
+ if ((fa == FieldAttributes.Family) || (fa == FieldAttributes.FamANDAssem)){
+ if (closure_invocation_type == null)
+ return false;
+
+ if (!IsSubclassOrNestedChildOf (closure_invocation_type, fi.DeclaringType))
+ return false;
+
+ // Although a derived class can access protected members of its base class
+ // it cannot do so through an instance of the base class (CS1540).
+ if (!fi.IsStatic && (closure_invocation_type != closure_qualifier_type) &&
+ (closure_qualifier_type != null) &&
+ closure_invocation_type.IsSubclassOf (closure_qualifier_type))
+ return false;
+
+ return true;
+ }
+
+ // Public.
return true;
}
//
- // EventInfos and PropertyInfos, return true
+ // EventInfos and PropertyInfos, return true because they lack permission
+ // informaiton, so we need to check later on the methods.
//
return true;
}
static MemberFilter FilterWithClosure_delegate = new MemberFilter (FilterWithClosure);
-
+
//
// Looks up a member called `name' in the `queried_type'. This lookup
- // is done by code that is contained in the definition for `invocation_type'.
+ // is done by code that is contained in the definition for `invocation_type'
+ // through a qualifier of type `qualifier_type' (or null if there is no qualifier).
+ //
+ // `invocation_type' is used to check whether we're allowed to access the requested
+ // member wrt its protection level.
+ //
+ // When called from MemberAccess, `qualifier_type' is the type which is used to access
+ // the requested member (`class B { A a = new A (); a.foo = 5; }'; here invocation_type
+ // is B and qualifier_type is A). This is used to do the CS1540 check.
+ //
+ // When resolving a SimpleName, `qualifier_type' is null.
+ //
+ // The `qualifier_type' is used for the CS1540 check; it's normally either null or
+ // the same than `queried_type' - except when we're being called from BaseAccess;
+ // in this case, `invocation_type' is the current type and `queried_type' the base
+ // type, so this'd normally trigger a CS1540.
//
// The binding flags are `bf' and the kind of members being looked up are `mt'
//
+ // The return value always includes private members which code in `invocation_type'
+ // is allowed to access (using the specified `qualifier_type' if given); only use
+ // BindingFlags.NonPublic to bypass the permission check.
+ //
// Returns an array of a single element for everything but Methods/Constructors
// that might return multiple matches.
//
- public static MemberInfo [] MemberLookup (Type invocation_type, Type queried_type,
- MemberTypes mt, BindingFlags original_bf, string name)
+ public static MemberInfo [] MemberLookup (Type invocation_type, Type qualifier_type,
+ Type queried_type, MemberTypes mt,
+ BindingFlags original_bf, string name)
+ {
+ Timer.StartTimer (TimerType.MemberLookup);
+
+ MemberInfo[] retval = RealMemberLookup (invocation_type, qualifier_type,
+ queried_type, mt, original_bf, name);
+
+ Timer.StopTimer (TimerType.MemberLookup);
+
+ return retval;
+ }
+
+ static MemberInfo [] RealMemberLookup (Type invocation_type, Type qualifier_type,
+ Type queried_type, MemberTypes mt,
+ BindingFlags original_bf, string name)
{
BindingFlags bf = original_bf;
ArrayList method_list = null;
Type current_type = queried_type;
bool searching = (original_bf & BindingFlags.DeclaredOnly) == 0;
- bool private_ok;
+ bool skip_iface_check = true, used_cache = false;
bool always_ok_flag = false;
closure_name = name;
closure_invocation_type = invocation_type;
closure_invocation_assembly = invocation_type != null ? invocation_type.Assembly : null;
+ closure_qualifier_type = qualifier_type;
//
// If we are a nested class, we always have access to our container
if (invocation_name.IndexOf ('+') != -1){
string container = queried_type.FullName + "+";
int container_length = container.Length;
-
+
if (invocation_name.Length > container_length){
string shared = invocation_name.Substring (0, container_length);
}
do {
- MemberInfo [] mi;
+ MemberList list;
//
// `NonPublic' is lame, because it includes both protected and
// public, private and protected (internal does not come into the
// equation)
//
- if (invocation_type != null){
- if (invocation_type == current_type){
- private_ok = true;
- } else
- private_ok = always_ok_flag;
-
- if (private_ok || invocation_type.IsSubclassOf (current_type))
- bf = original_bf | BindingFlags.NonPublic;
- } else {
- private_ok = false;
- bf = original_bf & ~BindingFlags.NonPublic;
- }
+ if ((invocation_type != null) &&
+ ((invocation_type == current_type) ||
+ IsNestedChildOf (invocation_type, current_type)) ||
+ always_ok_flag)
+ bf = original_bf | BindingFlags.NonPublic;
+ else
+ bf = original_bf;
- closure_private_ok = private_ok;
+ closure_private_ok = (bf & BindingFlags.NonPublic) != 0;
closure_queried_type = current_type;
-
- mi = TypeManager.FindMembers (
- current_type, mt, bf | BindingFlags.DeclaredOnly,
- FilterWithClosure_delegate, name);
-
+
+ Timer.StopTimer (TimerType.MemberLookup);
+
+ list = MemberLookup_FindMembers (current_type, mt, bf, name, out used_cache);
+
+ Timer.StartTimer (TimerType.MemberLookup);
+
+ //
+ // When queried for an interface type, the cache will automatically check all
+ // inherited members, so we don't need to do this here. However, this only
+ // works if we already used the cache in the first iteration of this loop.
+ //
+ // If we used the cache in any further iteration, we can still terminate the
+ // loop since the cache always looks in all parent classes.
+ //
+
+ if (used_cache)
+ searching = false;
+ else
+ skip_iface_check = false;
+
if (current_type == TypeManager.object_type)
searching = false;
else {
current_type = TypeManager.object_type;
}
- if (mi == null)
- continue;
-
- int count = mi.Length;
-
- if (count == 0)
+ if (list.Count == 0)
continue;
//
// searches, which means that our above FindMembers will
// return two copies of the same.
//
- if (count == 1 && !(mi [0] is MethodBase)){
- return mi;
+ if (list.Count == 1 && !(list [0] is MethodBase)){
+ return (MemberInfo []) list;
}
//
// Multiple properties: we query those just to find out the indexer
// name
//
- if (mi [0] is PropertyInfo)
- return mi;
-
+ if (list [0] is PropertyInfo)
+ return (MemberInfo []) list;
+
//
// We found methods, turn the search into "method scan"
// mode.
//
- method_list = CopyNewMethods (method_list, mi);
+ method_list = CopyNewMethods (method_list, list);
mt &= (MemberTypes.Method | MemberTypes.Constructor);
} while (searching);
if (method_list != null && method_list.Count > 0)
return (MemberInfo []) method_list.ToArray (typeof (MemberInfo));
-
+
+ //
+ // This happens if we already used the cache in the first iteration, in this case
+ // the cache already looked in all interfaces.
+ //
+ if (skip_iface_check)
+ return null;
+
//
// Interfaces do not list members they inherit, so we have to
// scan those.
foreach (Type itype in ifaces){
MemberInfo [] x;
- x = MemberLookup (null, itype, mt, bf, name);
+ x = MemberLookup (null, null, itype, mt, bf, name);
if (x != null)
return x;
}
}
+/// <summary>
+/// There is exactly one instance of this class per type.
+/// </summary>
+public sealed class TypeHandle : IMemberContainer {
+ public readonly TypeHandle BaseType;
+
+ readonly int id = ++next_id;
+ static int next_id = 0;
+
+ /// <summary>
+ /// Lookup a TypeHandle instance for the given type. If the type doesn't have
+ /// a TypeHandle yet, a new instance of it is created. This static method
+ /// ensures that we'll only have one TypeHandle instance per type.
+ /// </summary>
+ public static TypeHandle GetTypeHandle (Type t)
+ {
+ TypeHandle handle = (TypeHandle) type_hash [t];
+ if (handle != null)
+ return handle;
+
+ handle = new TypeHandle (t);
+ type_hash.Add (t, handle);
+ return handle;
+ }
+
+ /// <summary>
+ /// Returns the TypeHandle for TypeManager.object_type.
+ /// </summary>
+ public static IMemberContainer ObjectType {
+ get {
+ if (object_type != null)
+ return object_type;
+
+ object_type = GetTypeHandle (TypeManager.object_type);
+
+ return object_type;
+ }
+ }
+
+ /// <summary>
+ /// Returns the TypeHandle for TypeManager.array_type.
+ /// </summary>
+ public static IMemberContainer ArrayType {
+ get {
+ if (array_type != null)
+ return array_type;
+
+ array_type = GetTypeHandle (TypeManager.array_type);
+
+ return array_type;
+ }
+ }
+
+ private static PtrHashtable type_hash = new PtrHashtable ();
+
+ private static TypeHandle object_type = null;
+ private static TypeHandle array_type = null;
+
+ private Type type;
+ private bool is_interface;
+ private MemberCache member_cache;
+
+ private TypeHandle (Type type)
+ {
+ this.type = type;
+ if (type.BaseType != null)
+ BaseType = GetTypeHandle (type.BaseType);
+ else if ((type != TypeManager.object_type) && (type != typeof (object)))
+ is_interface = true;
+ this.member_cache = new MemberCache (this);
+ }
+
+ // IMemberContainer methods
+
+ public string Name {
+ get {
+ return type.FullName;
+ }
+ }
+
+ public Type Type {
+ get {
+ return type;
+ }
+ }
+
+ public IMemberContainer Parent {
+ get {
+ return BaseType;
+ }
+ }
+
+ public bool IsInterface {
+ get {
+ return is_interface;
+ }
+ }
+
+ public MemberList GetMembers (MemberTypes mt, BindingFlags bf)
+ {
+ if (mt == MemberTypes.Event)
+ return new MemberList (type.GetEvents (bf | BindingFlags.DeclaredOnly));
+ else
+ return new MemberList (type.FindMembers (mt, bf | BindingFlags.DeclaredOnly,
+ null, null));
+ }
+
+ // IMemberFinder methods
+
+ public MemberList FindMembers (MemberTypes mt, BindingFlags bf, string name,
+ MemberFilter filter, object criteria)
+ {
+ return member_cache.FindMembers (mt, bf, name, filter, criteria);
+ }
+
+ public MemberCache MemberCache {
+ get {
+ return member_cache;
+ }
+ }
+
+ public override string ToString ()
+ {
+ if (BaseType != null)
+ return "TypeHandle (" + id + "," + Name + " : " + BaseType + ")";
+ else
+ return "TypeHandle (" + id + "," + Name + ")";
+ }
+}
+
}