Loki/include/loki/SmartPtr.h

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////////////////////////////////////////////////////////////////////////////////
// The Loki Library
// Copyright (c) 2001 by Andrei Alexandrescu
// This code accompanies the book:
// Alexandrescu, Andrei. "Modern C++ Design: Generic Programming and Design
// Patterns Applied". Copyright (c) 2001. Addison-Wesley.
// Permission to use, copy, modify, distribute and sell this software for any
// purpose is hereby granted without fee, provided that the above copyright
// notice appear in all copies and that both that copyright notice and this
// permission notice appear in supporting documentation.
// The author or Addison-Wesley Longman make no representations about the
// suitability of this software for any purpose. It is provided "as is"
// without express or implied warranty.
////////////////////////////////////////////////////////////////////////////////
#ifndef LOKI_SMARTPTR_INC_
#define LOKI_SMARTPTR_INC_
////////////////////////////////////////////////////////////////////////////////
// IMPORTANT NOTE
// Due to threading issues, the OwnershipPolicy has been changed as follows:
// Release() returns a boolean saying if that was the last release
// so the pointer can be deleted by the StoragePolicy
// IsUnique() was removed
////////////////////////////////////////////////////////////////////////////////
#include "SmallObj.h"
#include "TypeManip.h"
#include "static_check.h"
#include <functional>
#include <stdexcept>
#include <cassert>
namespace Loki
{
////////////////////////////////////////////////////////////////////////////////
// class template DefaultSPStorage
// Implementation of the StoragePolicy used by SmartPtr
////////////////////////////////////////////////////////////////////////////////
template <class T>
class DefaultSPStorage
{
public:
typedef T* StoredType; // the type of the pointee_ object
typedef T* PointerType; // type returned by operator->
typedef T& ReferenceType; // type returned by operator*
DefaultSPStorage() : pointee_(Default())
{}
// The storage policy doesn't initialize the stored pointer
// which will be initialized by the OwnershipPolicy's Clone fn
DefaultSPStorage(const DefaultSPStorage&)
{}
template <class U>
DefaultSPStorage(const DefaultSPStorage<U>&)
{}
DefaultSPStorage(const StoredType& p) : pointee_(p) {}
PointerType operator->() const { return pointee_; }
ReferenceType operator*() const { return *pointee_; }
void Swap(DefaultSPStorage& rhs)
{ std::swap(pointee_, rhs.pointee_); }
// Accessors
friend inline PointerType GetImpl(const DefaultSPStorage& sp)
{ return sp.pointee_; }
friend inline const StoredType& GetImplRef(const DefaultSPStorage& sp)
{ return sp.pointee_; }
friend inline StoredType& GetImplRef(DefaultSPStorage& sp)
{ return sp.pointee_; }
protected:
// Destroys the data stored
// (Destruction might be taken over by the OwnershipPolicy)
void Destroy()
{ delete pointee_; }
// Default value to initialize the pointer
static StoredType Default()
{ return 0; }
private:
// Data
StoredType pointee_;
};
////////////////////////////////////////////////////////////////////////////////
// class template RefCounted
// Implementation of the OwnershipPolicy used by SmartPtr
// Provides a classic external reference counting implementation
////////////////////////////////////////////////////////////////////////////////
template <class P>
class RefCounted
{
public:
RefCounted()
{
pCount_ = static_cast<unsigned int*>(
SmallObject<>::operator new(sizeof(unsigned int)));
assert(pCount_);
*pCount_ = 1;
}
RefCounted(const RefCounted& rhs)
: pCount_(rhs.pCount_)
{}
// MWCW lacks template friends, hence the following kludge
template <typename P1>
RefCounted(const RefCounted<P1>& rhs)
: pCount_(reinterpret_cast<const RefCounted&>(rhs).pCount_)
{}
P Clone(const P& val)
{
++*pCount_;
return val;
}
bool Release(const P&)
{
if (!--*pCount_)
{
SmallObject<>::operator delete(pCount_, sizeof(unsigned int));
return true;
}
return false;
}
void Swap(RefCounted& rhs)
{ std::swap(pCount_, rhs.pCount_); }
enum { destructiveCopy = false };
private:
// Data
unsigned int* pCount_;
};
////////////////////////////////////////////////////////////////////////////////
// class template RefCountedMT
// Implementation of the OwnershipPolicy used by SmartPtr
// Implements external reference counting for multithreaded programs
// Policy Usage: RefCountedMTAdj<ThreadingModel>::RefCountedMT
////////////////////////////////////////////////////////////////////////////////
template <template <class> class ThreadingModel>
struct RefCountedMTAdj
{
template <class P>
class RefCountedMT : public ThreadingModel< RefCountedMT<P> >
{
typedef ThreadingModel< RefCountedMT<P> > base_type;
typedef typename base_type::IntType CountType;
typedef volatile CountType *CountPtrType;
public:
RefCountedMT()
{
pCount_ = static_cast<CountPtrType>(
SmallObject<ThreadingModel>::operator new(
sizeof(*pCount_)));
assert(pCount_);
//*pCount_ = 1;
ThreadingModel<RefCountedMT>::AtomicAssign(*pCount_, 1);
}
RefCountedMT(const RefCountedMT& rhs)
: pCount_(rhs.pCount_)
{}
//MWCW lacks template friends, hence the following kludge
template <typename P1>
RefCountedMT(const RefCountedMT<P1>& rhs)
: pCount_(reinterpret_cast<const RefCountedMT<P>&>(rhs).pCount_)
{}
P Clone(const P& val)
{
ThreadingModel<RefCountedMT>::AtomicIncrement(*pCount_);
return val;
}
bool Release(const P&)
{
if (!ThreadingModel<RefCountedMT>::AtomicDecrement(*pCount_))
{
SmallObject<ThreadingModel>::operator delete(
const_cast<CountType *>(pCount_),
sizeof(*pCount_));
return true;
}
return false;
}
void Swap(RefCountedMT& rhs)
{ std::swap(pCount_, rhs.pCount_); }
enum { destructiveCopy = false };
private:
// Data
CountPtrType pCount_;
};
};
////////////////////////////////////////////////////////////////////////////////
// class template COMRefCounted
// Implementation of the OwnershipPolicy used by SmartPtr
// Adapts COM intrusive reference counting to OwnershipPolicy-specific syntax
////////////////////////////////////////////////////////////////////////////////
template <class P>
class COMRefCounted
{
public:
COMRefCounted()
{}
template <class U>
COMRefCounted(const COMRefCounted<U>&)
{}
static P Clone(const P& val)
{
val->AddRef();
return val;
}
static bool Release(const P& val)
{ val->Release(); return false; }
enum { destructiveCopy = false };
static void Swap(COMRefCounted&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template DeepCopy
// Implementation of the OwnershipPolicy used by SmartPtr
// Implements deep copy semantics, assumes existence of a Clone() member
// function of the pointee type
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct DeepCopy
{
DeepCopy()
{}
template <class P1>
DeepCopy(const DeepCopy<P1>&)
{}
static P Clone(const P& val)
{ return val->Clone(); }
static bool Release(const P& val)
{ return true; }
static void Swap(DeepCopy&)
{}
enum { destructiveCopy = false };
};
////////////////////////////////////////////////////////////////////////////////
// class template RefLinked
// Implementation of the OwnershipPolicy used by SmartPtr
// Implements reference linking
////////////////////////////////////////////////////////////////////////////////
namespace Private
{
class RefLinkedBase
{
public:
RefLinkedBase()
{ prev_ = next_ = this; }
RefLinkedBase(const RefLinkedBase& rhs)
{
prev_ = &rhs;
next_ = rhs.next_;
prev_->next_ = this;
next_->prev_ = this;
}
bool Release()
{
if (next_ == this)
{
assert(prev_ == this);
return true;
}
prev_->next_ = next_;
next_->prev_ = prev_;
return false;
}
void Swap(RefLinkedBase& rhs)
{
if (next_ == this)
{
assert(prev_ == this);
if (rhs.next_ == &rhs)
{
assert(rhs.prev_ == &rhs);
// both lists are empty, nothing 2 do
return;
}
prev_ = rhs.prev_;
next_ = rhs.next_;
prev_->next_ = next_->prev_ = this;
rhs.next_ = rhs.prev_ = &rhs;
return;
}
if (rhs.next_ == &rhs)
{
rhs.Swap(*this);
return;
}
if (next_ == &rhs ) // neighbours
{
std::swap(prev_, next_);
std::swap(rhs.prev_, rhs.next_);
std::swap(rhs.prev_, next_);
std::swap(rhs.prev_->next_,next_->prev_);
}
else
{
std::swap(prev_, rhs.prev_);
std::swap(next_, rhs.next_);
std::swap(prev_->next_, rhs.prev_->next_);
std::swap(next_->prev_, rhs.next_->prev_);
}
assert( next_ == this ? prev_ == this : prev_ != this);
}
enum { destructiveCopy = false };
private:
mutable const RefLinkedBase* prev_;
mutable const RefLinkedBase* next_;
};
}
template <class P>
class RefLinked : public Private::RefLinkedBase
{
public:
RefLinked()
{}
template <class P1>
RefLinked(const RefLinked<P1>& rhs)
: Private::RefLinkedBase(rhs)
{}
static P Clone(const P& val)
{ return val; }
bool Release(const P&)
{ return Private::RefLinkedBase::Release(); }
};
////////////////////////////////////////////////////////////////////////////////
// class template DestructiveCopy
// Implementation of the OwnershipPolicy used by SmartPtr
// Implements destructive copy semantics (a la std::auto_ptr)
////////////////////////////////////////////////////////////////////////////////
template <class P>
class DestructiveCopy
{
public:
DestructiveCopy()
{}
template <class P1>
DestructiveCopy(const DestructiveCopy<P1>&)
{}
template <class P1>
static P Clone(P1& val)
{
P result(val);
val = P1();
return result;
}
static bool Release(const P&)
{ return true; }
static void Swap(DestructiveCopy&)
{}
enum { destructiveCopy = true };
};
////////////////////////////////////////////////////////////////////////////////
// class template NoCopy
// Implementation of the OwnershipPolicy used by SmartPtr
// Implements a policy that doesn't allow copying objects
////////////////////////////////////////////////////////////////////////////////
template <class P>
class NoCopy
{
public:
NoCopy()
{}
template <class P1>
NoCopy(const NoCopy<P1>&)
{}
static P Clone(const P&)
{
// Make it depended on template parameter
static const bool DependedFalse = sizeof(P*) == 0;
LOKI_STATIC_CHECK(DependedFalse, This_Policy_Disallows_Value_Copying);
}
static bool Release(const P&)
{ return true; }
static void Swap(NoCopy&)
{}
enum { destructiveCopy = false };
};
////////////////////////////////////////////////////////////////////////////////
// class template AllowConversion
// Implementation of the ConversionPolicy used by SmartPtr
// Allows implicit conversion from SmartPtr to the pointee type
////////////////////////////////////////////////////////////////////////////////
struct AllowConversion
{
enum { allow = true };
void Swap(AllowConversion&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template DisallowConversion
// Implementation of the ConversionPolicy used by SmartPtr
// Does not allow implicit conversion from SmartPtr to the pointee type
// You can initialize a DisallowConversion with an AllowConversion
////////////////////////////////////////////////////////////////////////////////
struct DisallowConversion
{
DisallowConversion()
{}
DisallowConversion(const AllowConversion&)
{}
enum { allow = false };
void Swap(DisallowConversion&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template NoCheck
// Implementation of the CheckingPolicy used by SmartPtr
// Well, it's clear what it does :o)
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct NoCheck
{
NoCheck()
{}
template <class P1>
NoCheck(const NoCheck<P1>&)
{}
static void OnDefault(const P&)
{}
static void OnInit(const P&)
{}
static void OnDereference(const P&)
{}
static void Swap(NoCheck&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template AssertCheck
// Implementation of the CheckingPolicy used by SmartPtr
// Checks the pointer before dereference
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct AssertCheck
{
AssertCheck()
{}
template <class P1>
AssertCheck(const AssertCheck<P1>&)
{}
template <class P1>
AssertCheck(const NoCheck<P1>&)
{}
static void OnDefault(const P&)
{}
static void OnInit(const P&)
{}
static void OnDereference(P val)
{ assert(val); (void)val; }
static void Swap(AssertCheck&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template AssertCheckStrict
// Implementation of the CheckingPolicy used by SmartPtr
// Checks the pointer against zero upon initialization and before dereference
// You can initialize an AssertCheckStrict with an AssertCheck
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct AssertCheckStrict
{
AssertCheckStrict()
{}
template <class U>
AssertCheckStrict(const AssertCheckStrict<U>&)
{}
template <class U>
AssertCheckStrict(const AssertCheck<U>&)
{}
template <class P1>
AssertCheckStrict(const NoCheck<P1>&)
{}
static void OnDefault(P val)
{ assert(val); }
static void OnInit(P val)
{ assert(val); }
static void OnDereference(P val)
{ assert(val); }
static void Swap(AssertCheckStrict&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class NullPointerException
// Used by some implementations of the CheckingPolicy used by SmartPtr
////////////////////////////////////////////////////////////////////////////////
struct NullPointerException : public std::runtime_error
{
NullPointerException() : std::runtime_error("")
{ }
const char* what() const throw()
{ return "Null Pointer Exception"; }
};
////////////////////////////////////////////////////////////////////////////////
// class template RejectNullStatic
// Implementation of the CheckingPolicy used by SmartPtr
// Checks the pointer upon initialization and before dereference
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct RejectNullStatic
{
RejectNullStatic()
{}
template <class P1>
RejectNullStatic(const RejectNullStatic<P1>&)
{}
template <class P1>
RejectNullStatic(const NoCheck<P1>&)
{}
template <class P1>
RejectNullStatic(const AssertCheck<P1>&)
{}
template <class P1>
RejectNullStatic(const AssertCheckStrict<P1>&)
{}
static void OnDefault(const P&)
{
// Make it depended on template parameter
static const bool DependedFalse = sizeof(P*) == 0;
LOKI_STATIC_CHECK(DependedFalse, ERROR_This_Policy_Does_Not_Allow_Default_Initialization);
}
static void OnInit(const P& val)
{ if (!val) throw NullPointerException(); }
static void OnDereference(const P& val)
{ if (!val) throw NullPointerException(); }
static void Swap(RejectNullStatic&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template RejectNull
// Implementation of the CheckingPolicy used by SmartPtr
// Checks the pointer before dereference
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct RejectNull
{
RejectNull()
{}
template <class P1>
RejectNull(const RejectNull<P1>&)
{}
static void OnInit(P val)
{ if (!val) throw NullPointerException(); }
static void OnDefault(P val)
{ OnInit(val); }
void OnDereference(P val)
{ OnInit(val); }
void Swap(RejectNull&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template RejectNullStrict
// Implementation of the CheckingPolicy used by SmartPtr
// Checks the pointer upon initialization and before dereference
////////////////////////////////////////////////////////////////////////////////
template <class P>
struct RejectNullStrict
{
RejectNullStrict()
{}
template <class P1>
RejectNullStrict(const RejectNullStrict<P1>&)
{}
template <class P1>
RejectNullStrict(const RejectNull<P1>&)
{}
static void OnInit(P val)
{ if (!val) throw NullPointerException(); }
void OnDereference(P val)
{ OnInit(val); }
void Swap(RejectNullStrict&)
{}
};
////////////////////////////////////////////////////////////////////////////////
// class template ByRef
// Transports a reference as a value
// Serves to implement the Colvin/Gibbons trick for SmartPtr
////////////////////////////////////////////////////////////////////////////////
template <class T>
class ByRef
{
public:
ByRef(T& v) : value_(v) {}
operator T&() { return value_; }
// gcc doesn't like this:
// operator const T&() const { return value_; }
private:
ByRef& operator=(const ByRef &);
T& value_;
};
////////////////////////////////////////////////////////////////////////////////
// class template SmartPtr (declaration)
// The reason for all the fuss above
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OwnershipPolicy = RefCounted,
class ConversionPolicy = DisallowConversion,
template <class> class CheckingPolicy = AssertCheck,
template <class> class StoragePolicy = DefaultSPStorage
>
class SmartPtr;
////////////////////////////////////////////////////////////////////////////////
// class template SmartPtrDef (definition)
// this class added to unify the usage of SmartPtr
// instead of writing SmartPtr<T,OP,CP,KP,SP> write SmartPtrDef<T,OP,CP,KP,SP>::type
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OwnershipPolicy = RefCounted,
class ConversionPolicy = DisallowConversion,
template <class> class CheckingPolicy = AssertCheck,
template <class> class StoragePolicy = DefaultSPStorage
>
struct SmartPtrDef
{
typedef SmartPtr
<
T,
OwnershipPolicy,
ConversionPolicy,
CheckingPolicy,
StoragePolicy
>
type;
};
////////////////////////////////////////////////////////////////////////////////
// class template SmartPtr (definition)
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OwnershipPolicy,
class ConversionPolicy,
template <class> class CheckingPolicy,
template <class> class StoragePolicy
>
class SmartPtr
: public StoragePolicy<T>
, public OwnershipPolicy<typename StoragePolicy<T>::PointerType>
, public CheckingPolicy<typename StoragePolicy<T>::StoredType>
, public ConversionPolicy
{
typedef StoragePolicy<T> SP;
typedef OwnershipPolicy<typename StoragePolicy<T>::PointerType> OP;
typedef CheckingPolicy<typename StoragePolicy<T>::StoredType> KP;
typedef ConversionPolicy CP;
public:
typedef typename SP::PointerType PointerType;
typedef typename SP::StoredType StoredType;
typedef typename SP::ReferenceType ReferenceType;
typedef typename Select<OP::destructiveCopy,
SmartPtr, const SmartPtr>::Result
CopyArg;
private:
struct NeverMatched;
#ifdef LOKI_SMARTPTR_CONVERSION_CONSTRUCTOR_POLICY
typedef typename Select< CP::allow, const StoredType&, NeverMatched>::Result ImplicitArg;
typedef typename Select<!CP::allow, const StoredType&, NeverMatched>::Result ExplicitArg;
#else
typedef const StoredType& ImplicitArg;
typedef typename Select<false, const StoredType&, NeverMatched>::Result ExplicitArg;
#endif
public:
SmartPtr()
{ KP::OnDefault(GetImpl(*this)); }
explicit
SmartPtr(ExplicitArg p) : SP(p)
{ KP::OnInit(GetImpl(*this)); }
SmartPtr(ImplicitArg p) : SP(p)
{ KP::OnInit(GetImpl(*this)); }
SmartPtr(CopyArg& rhs)
: SP(rhs), OP(rhs), KP(rhs), CP(rhs)
{ GetImplRef(*this) = OP::Clone(GetImplRef(rhs)); }
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
SmartPtr(const SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs)
: SP(rhs), OP(rhs), KP(rhs), CP(rhs)
{ GetImplRef(*this) = OP::Clone(GetImplRef(rhs)); }
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
SmartPtr(SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs)
: SP(rhs), OP(rhs), KP(rhs), CP(rhs)
{ GetImplRef(*this) = OP::Clone(GetImplRef(rhs)); }
SmartPtr(ByRef<SmartPtr> rhs)
: SP(rhs), OP(rhs), KP(rhs), CP(rhs)
{}
operator ByRef<SmartPtr>()
{ return ByRef<SmartPtr>(*this); }
SmartPtr& operator=(CopyArg& rhs)
{
SmartPtr temp(rhs);
temp.Swap(*this);
return *this;
}
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
SmartPtr& operator=(const SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs)
{
SmartPtr temp(rhs);
temp.Swap(*this);
return *this;
}
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
SmartPtr& operator=(SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs)
{
SmartPtr temp(rhs);
temp.Swap(*this);
return *this;
}
void Swap(SmartPtr& rhs)
{
OP::Swap(rhs);
CP::Swap(rhs);
KP::Swap(rhs);
SP::Swap(rhs);
}
~SmartPtr()
{
if (OP::Release(GetImpl(*static_cast<SP*>(this))))
{
SP::Destroy();
}
}
friend inline void Release(SmartPtr& sp, typename SP::StoredType& p)
{
p = GetImplRef(sp);
GetImplRef(sp) = SP::Default();
}
friend inline void Reset(SmartPtr& sp, typename SP::StoredType p)
{ SmartPtr(p).Swap(sp); }
PointerType operator->()
{
KP::OnDereference(GetImplRef(*this));
return SP::operator->();
}
PointerType operator->() const
{
KP::OnDereference(GetImplRef(*this));
return SP::operator->();
}
ReferenceType operator*()
{
KP::OnDereference(GetImplRef(*this));
return SP::operator*();
}
ReferenceType operator*() const
{
KP::OnDereference(GetImplRef(*this));
return SP::operator*();
}
bool operator!() const // Enables "if (!sp) ..."
{ return GetImpl(*this) == 0; }
// Ambiguity buster
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
bool operator==(const SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs) const
{ return GetImpl(*this) == GetImpl(rhs); }
// Ambiguity buster
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
bool operator!=(const SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs) const
{ return !(*this == rhs); }
// Ambiguity buster
template
<
typename T1,
template <class> class OP1,
class CP1,
template <class> class KP1,
template <class> class SP1
>
bool operator<(const SmartPtr<T1, OP1, CP1, KP1, SP1>& rhs) const
{ return GetImpl(*this) < GetImpl(rhs); }
private:
// Helper for enabling 'if (sp)'
struct Tester
{
Tester(int) {}
void dummy() {}
};
typedef void (Tester::*unspecified_boolean_type_)();
typedef typename Select<CP::allow, Tester, unspecified_boolean_type_>::Result
unspecified_boolean_type;
public:
// enable 'if (sp)'
operator unspecified_boolean_type() const
{
return !*this ? 0 : &Tester::dummy;
}
private:
// Helper for disallowing automatic conversion
struct Insipid
{
Insipid(PointerType) {}
};
typedef typename Select<CP::allow, PointerType, Insipid>::Result
AutomaticConversionResult;
public:
operator AutomaticConversionResult() const
{ return GetImpl(*this); }
};
////////////////////////////////////////////////////////////////////////////////
// free comparison operators for class template SmartPtr
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// operator== for lhs = SmartPtr, rhs = raw pointer
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator==(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs)
{ return GetImpl(lhs) == rhs; }
////////////////////////////////////////////////////////////////////////////////
// operator== for lhs = raw pointer, rhs = SmartPtr
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator==(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs)
{ return rhs == lhs; }
////////////////////////////////////////////////////////////////////////////////
// operator!= for lhs = SmartPtr, rhs = raw pointer
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator!=(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs)
{ return !(lhs == rhs); }
////////////////////////////////////////////////////////////////////////////////
// operator!= for lhs = raw pointer, rhs = SmartPtr
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator!=(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs)
{ return rhs != lhs; }
////////////////////////////////////////////////////////////////////////////////
// operator< for lhs = SmartPtr, rhs = raw pointer -- NOT DEFINED
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator<(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs);
////////////////////////////////////////////////////////////////////////////////
// operator< for lhs = raw pointer, rhs = SmartPtr -- NOT DEFINED
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator<(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs);
////////////////////////////////////////////////////////////////////////////////
// operator> for lhs = SmartPtr, rhs = raw pointer -- NOT DEFINED
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator>(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs)
{ return rhs < lhs; }
////////////////////////////////////////////////////////////////////////////////
// operator> for lhs = raw pointer, rhs = SmartPtr
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator>(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs)
{ return rhs < lhs; }
////////////////////////////////////////////////////////////////////////////////
// operator<= for lhs = SmartPtr, rhs = raw pointer
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator<=(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs)
{ return !(rhs < lhs); }
////////////////////////////////////////////////////////////////////////////////
// operator<= for lhs = raw pointer, rhs = SmartPtr
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator<=(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs)
{ return !(rhs < lhs); }
////////////////////////////////////////////////////////////////////////////////
// operator>= for lhs = SmartPtr, rhs = raw pointer
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator>=(const SmartPtr<T, OP, CP, KP, SP>& lhs,
U* rhs)
{ return !(lhs < rhs); }
////////////////////////////////////////////////////////////////////////////////
// operator>= for lhs = raw pointer, rhs = SmartPtr
////////////////////////////////////////////////////////////////////////////////
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP,
typename U
>
inline bool operator>=(U* lhs,
const SmartPtr<T, OP, CP, KP, SP>& rhs)
{ return !(lhs < rhs); }
} // namespace Loki
////////////////////////////////////////////////////////////////////////////////
// specialization of std::less for SmartPtr
////////////////////////////////////////////////////////////////////////////////
namespace std
{
template
<
typename T,
template <class> class OP,
class CP,
template <class> class KP,
template <class> class SP
>
struct less< Loki::SmartPtr<T, OP, CP, KP, SP> >
: public binary_function<Loki::SmartPtr<T, OP, CP, KP, SP>,
Loki::SmartPtr<T, OP, CP, KP, SP>, bool>
{
bool operator()(const Loki::SmartPtr<T, OP, CP, KP, SP>& lhs,
const Loki::SmartPtr<T, OP, CP, KP, SP>& rhs) const
{ return less<T*>()(GetImpl(lhs), GetImpl(rhs)); }
};
}
////////////////////////////////////////////////////////////////////////////////
// Change log:
// June 20, 2001: ported by Nick Thurn to gcc 2.95.3. Kudos, Nick!!!
// December 09, 2001: Included <cassert>
// February 2, 2003: fixed dependent names - credit due to Rani Sharoni
// August 21, 2003: Added support for policy based explicit/implicit constructor.
// The new code will be effective if a macro named
// *** LOKI_SMARTPTR_CONVERSION_CONSTRUCTOR_POLICY ***
// is defined (due to backward computability concerns).
// In case that the macro is defined and the conversion policy allow flag is off
// (e.g. DisallowConversion) then the conversion from the "pointer" to the
// SmartPtr must be explicit.
// October 32, 2005: fix void Swap(RefLinkedBase& rhs). Peter K<>mmel
////////////////////////////////////////////////////////////////////////////////
#endif // SMARTPTR_INC_