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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
// See the LICENSE file in the project root for more information.
//
// File: typehandle.inl
//
//
//
// ============================================================================
#ifndef _TYPEHANDLE_INL_
#define _TYPEHANDLE_INL_
#include "typehandle.h"
inline mdTypeDef TypeHandle::GetCl() const
{
LIMITED_METHOD_DAC_CONTRACT;
PREFIX_ASSUME(GetMethodTable() != NULL);
return GetMethodTable()->GetCl();
}
inline PTR_MethodTable TypeHandle::GetMethodTable() const
{
LIMITED_METHOD_DAC_CONTRACT;
if (IsTypeDesc())
return(AsTypeDesc()->GetMethodTable());
else
return AsMethodTable();
}
inline void TypeHandle::SetIsFullyLoaded()
{
LIMITED_METHOD_CONTRACT;
if (IsTypeDesc())
return AsTypeDesc()->SetIsFullyLoaded();
else
return AsMethodTable()->SetIsFullyLoaded();
}
inline MethodTable* TypeHandle::GetMethodTableOfElementType() const
{
LIMITED_METHOD_CONTRACT;
if (IsTypeDesc())
{
TypeHandle elementType = AsTypeDesc()->GetTypeParam();
return elementType.GetMethodTableOfElementType();
}
else
{
return AsMethodTable();
}
}
inline MethodTable * TypeHandle::GetPossiblySharedArrayMethodTable() const
{
LIMITED_METHOD_CONTRACT;
_ASSERTE(IsArrayType());
if (IsArray())
return AsArray()->GetTemplateMethodTable();
else
return AsMethodTable();
}
inline TypeHandle TypeHandle::GetElementType() const
{
LIMITED_METHOD_CONTRACT;
if (IsTypeDesc())
{
if (IsGenericVariable())
return *this;
return AsTypeDesc()->GetTypeParam().GetElementType();
}
else
{
return *this;
}
}
inline BOOL TypeHandle::IsZapped() const
{
LIMITED_METHOD_DAC_CONTRACT;
return (GetZapModule() != NULL);
}
inline PTR_ArrayTypeDesc TypeHandle::AsArray() const
{
LIMITED_METHOD_DAC_CONTRACT;
_ASSERTE(IsArray());
PTR_ArrayTypeDesc result = PTR_ArrayTypeDesc(m_asTAddr - 2);
PREFIX_ASSUME(result != NULL);
return result;
}
// Methods to allow you get get a the two possible representations
inline PTR_MethodTable TypeHandle::AsMethodTable() const
{
LIMITED_METHOD_DAC_CONTRACT;
_ASSERTE(!IsTypeDesc());
return PTR_MethodTable(m_asTAddr);
}
inline PTR_TypeDesc TypeHandle::AsTypeDesc() const
{
LIMITED_METHOD_DAC_CONTRACT;
_ASSERTE(IsTypeDesc());
PTR_TypeDesc result = PTR_TypeDesc(m_asTAddr - 2);
PREFIX_ASSUME(result != NULL);
return result;
}
inline FnPtrTypeDesc* TypeHandle::AsFnPtrType() const
{
LIMITED_METHOD_DAC_CONTRACT;
_ASSERTE(IsFnPtrType());
FnPtrTypeDesc* result = PTR_FnPtrTypeDesc(m_asTAddr - 2);
PREFIX_ASSUME(result != NULL);
return result;
}
inline TypeVarTypeDesc* TypeHandle::AsGenericVariable() const
{
LIMITED_METHOD_DAC_CONTRACT;
_ASSERTE(IsGenericVariable());
TypeVarTypeDesc* result = PTR_TypeVarTypeDesc(m_asTAddr - 2);
PREFIX_ASSUME(result != NULL);
return result;
}
inline BOOL TypeHandle::IsNativeValueType() const
{
LIMITED_METHOD_DAC_CONTRACT;
return (IsTypeDesc() && AsTypeDesc()->IsNativeValueType());
}
inline MethodTable *TypeHandle::AsNativeValueType() const
{
LIMITED_METHOD_CONTRACT;
_ASSERTE(IsNativeValueType());
return AsTypeDesc()->GetMethodTable();
}
inline BOOL TypeHandle::IsTypicalTypeDefinition() const
{
LIMITED_METHOD_CONTRACT;
return !HasInstantiation() || IsGenericTypeDefinition();
}
inline BOOL TypeHandle::SupportsGenericInterop(InteropKind interopKind) const
{
LIMITED_METHOD_CONTRACT;
return (!IsTypeDesc() && AsMethodTable()->SupportsGenericInterop(interopKind));
}
inline BOOL TypeHandle::HasTypeEquivalence() const
{
LIMITED_METHOD_CONTRACT;
if (IsTypeDesc())
return AsTypeDesc()->HasTypeEquivalence();
else
return AsMethodTable()->HasTypeEquivalence();
}
//--------------------------------------------------------------------------------------
// IsEquivalentTo is based on Guid and TypeIdentifier attributes to support the "no-PIA"
// feature. The idea is that compilers pull types from the PIA into different assemblies
// and these types - represented by separate MTs/TypeHandles - are considered equivalent
// for certain operations.
#ifndef DACCESS_COMPILE
inline BOOL TypeHandle::IsEquivalentTo(TypeHandle type COMMA_INDEBUG(TypeHandlePairList *pVisited /*= NULL*/)) const
{
CONTRACTL
{
THROWS;
GC_TRIGGERS;
MODE_ANY;
SO_TOLERANT;
}
CONTRACTL_END;
if (*this == type)
return TRUE;
#ifdef FEATURE_TYPEEQUIVALENCE
// bail early for normal types
if (!HasTypeEquivalence() || !type.HasTypeEquivalence())
return FALSE;
if (IsTypeDesc())
return AsTypeDesc()->IsEquivalentTo(type COMMA_INDEBUG(pVisited));
if (type.IsTypeDesc())
return FALSE;
return AsMethodTable()->IsEquivalentTo_Worker(type.AsMethodTable() COMMA_INDEBUG(pVisited));
#else
return FALSE;
#endif
}
#endif
// Execute the callback functor for each MethodTable that makes up the given type handle. This method
// does not invoke the functor for generic variables
template<class T>
inline void TypeHandle::ForEachComponentMethodTable(T &callback) const
{
CONTRACTL
{
THROWS;
GC_TRIGGERS;
MODE_ANY;
}
CONTRACTL_END;
if (IsTypeDesc() && AsTypeDesc()->HasTypeParam())
{
// If we have a type parameter, then we just need to invoke ourselves on that parameter
AsTypeDesc()->GetTypeParam().ForEachComponentMethodTable(callback);
}
else if (IsFnPtrType())
{
// If we are a function pointer, then we need to invoke the callback method on the function
// pointer's return type as well as each of its argument types
FnPtrTypeDesc *pFnPtr = AsFnPtrType();
for (DWORD iArg = 0; iArg < pFnPtr->GetNumArgs() + 1; ++iArg)
{
pFnPtr->GetRetAndArgTypesPointer()[iArg].ForEachComponentMethodTable(callback);
}
}
else if (HasInstantiation())
{
// If we have a generic instantiation, we need to invoke the callback on each of the generic
// parameters as well as the root method table.
callback(GetMethodTable());
Instantiation instantiation = GetInstantiation();
for (DWORD iGenericArg = 0; iGenericArg < instantiation.GetNumArgs(); ++iGenericArg)
{
instantiation[iGenericArg].ForEachComponentMethodTable(callback);
}
}
else if (IsGenericVariable())
{
// We don't invoke the callback on generic variables since they don't have method tables
return;
}
else
{
// Otherwise, we must be a simple type, so just do the callback directly on the method table
callback(GetMethodTable());
}
}
#endif // _TYPEHANDLE_INL_
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