Map;
resize(aMap.size());
AssertReturnVoid(!isNull());
int i = 0;
for (typename Map::const_iterator it = aMap.begin();
it != aMap.end(); ++ it, ++ i)
#ifdef VBOX_WITH_XPCOM
Copy(it->second, m.arr[i]);
#else
Copy(it->second, m.raw[i]);
#endif
}
/**
* Destroys this instance after calling #setNull() to release allocated
* resources. See #setNull() for more details.
*/
virtual ~SafeArray() { setNull(); }
/**
* Returns @c true if this instance represents a null array.
*/
bool isNull() const { return m.arr == NULL; }
/**
* Returns @c true if this instance does not represents a null array.
*/
bool isNotNull() const { return m.arr != NULL; }
/**
* Resets this instance to null and, if this instance is not a weak one,
* releases any resources occupied by the array data.
*
* @note This method destroys (cleans up) all elements of the array using
* the corresponding cleanup routine for the element type before the
* array itself is destroyed.
*/
virtual void setNull() { m.uninit(); }
/**
* Returns @c true if this instance is weak. A weak instance doesn't own the
* array data and therefore operations manipulating the ownership (e.g.
* #detachTo()) are forbidden and will assert.
*/
bool isWeak() const { return m.isWeak; }
/** Number of elements in the array. */
size_t size() const
{
#ifdef VBOX_WITH_XPCOM
if (m.arr)
return m.size;
return 0;
#else
if (m.arr)
return Size(m.arr->rgsabound[0].cElements);
return 0;
#endif
}
/**
* Appends a copy of the given element at the end of the array.
*
* The array size is increased by one by this method and the additional
* space is allocated as needed.
*
* This method is handy in cases where you want to assign a copy of the
* existing value to the array element, for example:
* Bstr string; array.push_back(string);. If you create a string
* just to put it in the array, you may find #appendedRaw() more useful.
*
* @param aElement Element to append.
*
* @return @c true on success and @c false if there is not enough
* memory for resizing.
*/
bool push_back(const T &aElement)
{
if (!ensureCapacity(size() + 1))
return false;
#ifdef VBOX_WITH_XPCOM
SafeArray::Copy(aElement, m.arr[m.size]);
++ m.size;
#else
Copy(aElement, m.raw[size() - 1]);
#endif
return true;
}
/**
* Appends an empty element at the end of the array and returns a raw
* pointer to it suitable for assigning a raw value (w/o constructing a
* copy).
*
* The array size is increased by one by this method and the additional
* space is allocated as needed.
*
* Note that in case of raw assignment, value ownership (for types with
* dynamically allocated data and for interface pointers) is transferred to
* the safe array object.
*
* This method is handy for operations like
* Bstr("foo").detachTo(array.appendedRaw());. Don't use it as
* an l-value (array.appendedRaw() = SysAllocString(L"tralala");)
* since this doesn't check for a NULL condition; use #resize() and
* #setRawAt() instead. If you need to assign a copy of the existing value
* instead of transferring the ownership, look at #push_back().
*
* @return Raw pointer to the added element or NULL if no memory.
*/
T *appendedRaw()
{
if (!ensureCapacity(size() + 1))
return NULL;
#ifdef VBOX_WITH_XPCOM
SafeArray::Init(m.arr[m.size]);
++ m.size;
return &m.arr[m.size - 1];
#else
/* nothing to do here, SafeArrayCreate() has performed element
* initialization */
return &m.raw[size() - 1];
#endif
}
/**
* Resizes the array preserving its contents when possible. If the new size
* is larger than the old size, new elements are initialized with null
* values. If the new size is less than the old size, the contents of the
* array beyond the new size is lost.
*
* @param aNewSize New number of elements in the array.
* @return @c true on success and @c false if there is not enough
* memory for resizing.
*/
bool resize(size_t aNewSize)
{
if (!ensureCapacity(aNewSize))
return false;
#ifdef VBOX_WITH_XPCOM
if (m.size < aNewSize)
{
/* initialize the new elements */
for (size_t i = m.size; i < aNewSize; ++ i)
SafeArray::Init(m.arr[i]);
}
m.size = aNewSize;
#else
/* nothing to do here, SafeArrayCreate() has performed element
* initialization */
#endif
return true;
}
/**
* Reinitializes this instance by preallocating space for the given number
* of elements. The previous array contents is lost.
*
* @param aNewSize New number of elements in the array.
* @return @c true on success and @c false if there is not enough
* memory for resizing.
*/
bool reset(size_t aNewSize)
{
m.uninit();
return resize(aNewSize);
}
/**
* Returns a pointer to the raw array data. Use this raw pointer with care
* as no type or bound checking is done for you in this case.
*
* @note This method returns @c NULL when this instance is null.
* @see #operator[]
*/
T *raw()
{
#ifdef VBOX_WITH_XPCOM
return m.arr;
#else
return m.raw;
#endif
}
/**
* Const version of #raw().
*/
const T *raw() const
{
#ifdef VBOX_WITH_XPCOM
return m.arr;
#else
return m.raw;
#endif
}
/**
* Array access operator that returns an array element by reference. A bit
* safer than #raw(): asserts and returns an invalid reference if this
* instance is null or if the index is out of bounds.
*
* @note For weak instances, this call will succeed but the behavior of
* changing the contents of an element of the weak array instance is
* undefined and may lead to a program crash on some platforms.
*/
T &operator[] (size_t aIdx)
{
AssertReturn(m.arr != NULL, *((T *)NULL));
AssertReturn(aIdx < size(), *((T *)NULL));
#ifdef VBOX_WITH_XPCOM
return m.arr[aIdx];
#else
AssertReturn(m.raw != NULL, *((T *)NULL));
return m.raw[aIdx];
#endif
}
/**
* Const version of #operator[] that returns an array element by value.
*/
const T operator[] (size_t aIdx) const
{
AssertReturn(m.arr != NULL, *((T *)NULL));
AssertReturn(aIdx < size(), *((T *)NULL));
#ifdef VBOX_WITH_XPCOM
return m.arr[aIdx];
#else
AssertReturn(m.raw != NULL, *((T *)NULL));
return m.raw[aIdx];
#endif
}
/**
* Creates a copy of this array and stores it in a method parameter declared
* using the ComSafeArrayOut macro. When using this call, always wrap the
* parameter name in the ComSafeArrayOutArg macro call like this:
*
* safeArray.cloneTo(ComSafeArrayOutArg(aArg));
*
*
* @note It is assumed that the ownership of the returned copy is
* transferred to the caller of the method and he is responsible to free the
* array data when it is no longer needed.
*
* @param aArg Output method parameter to clone to.
*/
virtual const SafeArray &cloneTo(ComSafeArrayOut(T, aArg)) const
{
/// @todo Implement me!
#ifdef VBOX_WITH_XPCOM
NOREF(aArgSize);
NOREF(aArg);
#else
NOREF(aArg);
#endif
AssertFailedReturn(*this);
}
void cloneTo(SafeArray& aOther) const
{
aOther.reset(size());
aOther.initFrom(*this);
}
/**
* Transfers the ownership of this array's data to the specified location
* declared using the ComSafeArrayOut macro and makes this array a null
* array. When using this call, always wrap the parameter name in the
* ComSafeArrayOutArg macro call like this:
*
* safeArray.detachTo(ComSafeArrayOutArg(aArg));
*
*
* Detaching the null array is also possible in which case the location will
* receive NULL.
*
* @note Since the ownership of the array data is transferred to the
* caller of the method, he is responsible to free the array data when it is
* no longer needed.
*
* @param aArg Location to detach to.
*/
virtual SafeArray &detachTo(ComSafeArrayOut(T, aArg))
{
AssertReturn(!m.isWeak, *this);
#ifdef VBOX_WITH_XPCOM
AssertReturn(aArgSize != NULL, *this);
AssertReturn(aArg != NULL, *this);
*aArgSize = m.size;
*aArg = m.arr;
m.isWeak = false;
m.size = 0;
m.arr = NULL;
#else /* !VBOX_WITH_XPCOM */
AssertReturn(aArg != NULL, *this);
*aArg = m.arr;
if (m.raw)
{
HRESULT rc = SafeArrayUnaccessData(m.arr);
AssertComRCReturn(rc, *this);
m.raw = NULL;
}
m.isWeak = false;
m.arr = NULL;
#endif /* !VBOX_WITH_XPCOM */
return *this;
}
/**
* Returns a copy of this SafeArray as RTCList.
*/
RTCList toList()
{
RTCList list(size());
for (size_t i = 0; i < size(); ++i)
#ifdef VBOX_WITH_XPCOM
list.append(m.arr[i]);
#else
list.append(m.raw[i]);
#endif
return list;
}
inline void initFrom(const com::SafeArray & aRef);
inline void initFrom(const T* aPtr, size_t aSize);
// Public methods for internal purposes only.
#ifdef VBOX_WITH_XPCOM
/** Internal function. Never call it directly. */
PRUint32 *__asOutParam_Size() { setNull(); return &m.size; }
/** Internal function Never call it directly. */
T **__asOutParam_Arr() { Assert(isNull()); return &m.arr; }
#else /* !VBOX_WITH_XPCOM */
/** Internal function Never call it directly. */
SAFEARRAY * __asInParam() { return m.arr; }
/** Internal function Never call it directly. */
OutSafeArrayDipper __asOutParam()
{ setNull(); return OutSafeArrayDipper(&m.arr, (void **)&m.raw); }
#endif /* !VBOX_WITH_XPCOM */
static const SafeArray Null;
protected:
DECLARE_CLS_COPY_CTOR_ASSIGN_NOOP(SafeArray)
/**
* Ensures that the array is big enough to contain aNewSize elements.
*
* If the new size is greater than the current capacity, a new array is
* allocated and elements from the old array are copied over. The size of
* the array doesn't change, only the capacity increases (which is always
* greater than the size). Note that the additionally allocated elements are
* left uninitialized by this method.
*
* If the new size is less than the current size, the existing array is
* truncated to the specified size and the elements outside the new array
* boundary are freed.
*
* If the new size is the same as the current size, nothing happens.
*
* @param aNewSize New size of the array.
*
* @return @c true on success and @c false if not enough memory.
*/
bool ensureCapacity(size_t aNewSize)
{
AssertReturn(!m.isWeak, false);
#ifdef VBOX_WITH_XPCOM
/* Note: we distinguish between a null array and an empty (zero
* elements) array. Therefore we never use zero in malloc (even if
* aNewSize is zero) to make sure we get a non-null pointer. */
if (m.size == aNewSize && m.arr != NULL)
return true;
/* Allocate in 16-byte pieces. */
size_t newCapacity = RT_MAX((aNewSize + 15) / 16 * 16, 16);
if (m.capacity != newCapacity)
{
T *newArr = (T *)nsMemory::Alloc(RT_MAX(newCapacity, 1) * sizeof(T));
AssertReturn(newArr != NULL, false);
if (m.arr != NULL)
{
if (m.size > aNewSize)
{
/* Truncation takes place, uninit exceeding elements and
* shrink the size. */
for (size_t i = aNewSize; i < m.size; ++ i)
SafeArray::Uninit(m.arr[i]);
m.size = aNewSize;
}
/* Copy the old contents. */
memcpy(newArr, m.arr, m.size * sizeof(T));
nsMemory::Free((void *)m.arr);
}
m.arr = newArr;
}
else
{
if (m.size > aNewSize)
{
/* Truncation takes place, uninit exceeding elements and
* shrink the size. */
for (size_t i = aNewSize; i < m.size; ++ i)
SafeArray::Uninit(m.arr[i]);
m.size = aNewSize;
}
}
m.capacity = newCapacity;
#else
SAFEARRAYBOUND bound = { VarCount(aNewSize), 0 };
HRESULT rc;
if (m.arr == NULL)
{
m.arr = CreateSafeArray(VarType(), &bound);
AssertReturn(m.arr != NULL, false);
}
else
{
SafeArrayUnaccessData(m.arr);
rc = SafeArrayRedim(m.arr, &bound);
AssertComRCReturn(rc == S_OK, false);
}
rc = SafeArrayAccessData(m.arr, (void HUGEP **)&m.raw);
AssertComRCReturn(rc, false);
#endif
return true;
}
struct Data
{
Data()
: isWeak(false)
#ifdef VBOX_WITH_XPCOM
, capacity(0), size(0), arr(NULL)
#else
, arr(NULL), raw(NULL)
#endif
{}
~Data() { uninit(); }
void uninit()
{
#ifdef VBOX_WITH_XPCOM
if (arr)
{
if (!isWeak)
{
for (size_t i = 0; i < size; ++ i)
SafeArray::Uninit(arr[i]);
nsMemory::Free((void *)arr);
}
else
isWeak = false;
arr = NULL;
}
size = capacity = 0;
#else /* !VBOX_WITH_XPCOM */
if (arr)
{
if (raw)
{
SafeArrayUnaccessData(arr);
raw = NULL;
}
if (!isWeak)
{
HRESULT rc = SafeArrayDestroy(arr);
AssertComRCReturnVoid(rc);
}
else
isWeak = false;
arr = NULL;
}
#endif /* !VBOX_WITH_XPCOM */
}
bool isWeak : 1;
#ifdef VBOX_WITH_XPCOM
PRUint32 capacity;
PRUint32 size;
T *arr;
#else
SAFEARRAY *arr;
T *raw;
#endif
};
Data m;
};
/* Few fast specializations for primitive array types */
template<>
inline void com::SafeArray::initFrom(const com::SafeArray & aRef)
{
size_t sSize = aRef.size();
resize(sSize);
::memcpy(raw(), aRef.raw(), sSize);
}
template<>
inline void com::SafeArray::initFrom(const BYTE* aPtr, size_t aSize)
{
resize(aSize);
::memcpy(raw(), aPtr, aSize);
}
template<>
inline void com::SafeArray::initFrom(const com::SafeArray & aRef)
{
size_t sSize = aRef.size();
resize(sSize);
::memcpy(raw(), aRef.raw(), sSize * sizeof(SHORT));
}
template<>
inline void com::SafeArray::initFrom(const SHORT* aPtr, size_t aSize)
{
resize(aSize);
::memcpy(raw(), aPtr, aSize * sizeof(SHORT));
}
template<>
inline void com::SafeArray::initFrom(const com::SafeArray & aRef)
{
size_t sSize = aRef.size();
resize(sSize);
::memcpy(raw(), aRef.raw(), sSize * sizeof(USHORT));
}
template<>
inline void com::SafeArray::initFrom(const USHORT* aPtr, size_t aSize)
{
resize(aSize);
::memcpy(raw(), aPtr, aSize * sizeof(USHORT));
}
template<>
inline void com::SafeArray::initFrom(const com::SafeArray & aRef)
{
size_t sSize = aRef.size();
resize(sSize);
::memcpy(raw(), aRef.raw(), sSize * sizeof(LONG));
}
template<>
inline void com::SafeArray::initFrom(const LONG* aPtr, size_t aSize)
{
resize(aSize);
::memcpy(raw(), aPtr, aSize * sizeof(LONG));
}
////////////////////////////////////////////////////////////////////////////////
#ifdef VBOX_WITH_XPCOM
/**
* Version of com::SafeArray for arrays of GUID.
*
* In MS COM, GUID arrays store GUIDs by value and therefore input arrays are
* represented using |GUID *| and out arrays -- using |GUID **|. In XPCOM,
* GUID arrays store pointers to nsID so that input arrays are |const nsID **|
* and out arrays are |nsID ***|. Due to this difference, it is impossible to
* work with arrays of GUID on both platforms by simply using com::SafeArray
* . This class is intended to provide some level of cross-platform
* behavior.
*
* The basic usage pattern is basically similar to com::SafeArray<> except that
* you use ComSafeGUIDArrayIn* and ComSafeGUIDArrayOut* macros instead of
* ComSafeArrayIn* and ComSafeArrayOut*. Another important nuance is that the
* raw() array type is different (nsID **, or GUID ** on XPCOM and GUID * on MS
* COM) so it is recommended to use operator[] instead which always returns a
* GUID by value.
*
* Note that due to const modifiers, you cannot use SafeGUIDArray for input GUID
* arrays. Please use SafeConstGUIDArray for this instead.
*
* Other than mentioned above, the functionality of this class is equivalent to
* com::SafeArray<>. See the description of that template and its methods for
* more information.
*
* Output GUID arrays are handled by a separate class, SafeGUIDArrayOut, since
* this class cannot handle them because of const modifiers.
*/
class SafeGUIDArray : public SafeArray
{
public:
typedef SafeArray Base;
class nsIDRef
{
public:
nsIDRef(nsID * &aVal) : mVal(aVal) {}
operator const nsID &() const { return mVal ? *mVal : *Empty; }
operator nsID() const { return mVal ? *mVal : *Empty; }
const nsID *operator&() const { return mVal ? mVal : Empty; }
nsIDRef &operator= (const nsID &aThat)
{
if (mVal == NULL)
Copy(&aThat, mVal);
else
*mVal = aThat;
return *this;
}
private:
nsID * &mVal;
static const nsID *Empty;
friend class SafeGUIDArray;
};
/** See SafeArray<>::SafeArray(). */
SafeGUIDArray() {}
/** See SafeArray<>::SafeArray(size_t). */
SafeGUIDArray(size_t aSize) : Base(aSize) {}
/**
* Array access operator that returns an array element by reference. As a
* special case, the return value of this operator on XPCOM is an nsID (GUID)
* reference, instead of an nsID pointer (the actual SafeArray template
* argument), for compatibility with the MS COM version.
*
* The rest is equivalent to SafeArray<>::operator[].
*/
nsIDRef operator[] (size_t aIdx)
{
Assert(m.arr != NULL);
Assert(aIdx < size());
return nsIDRef(m.arr[aIdx]);
}
/**
* Const version of #operator[] that returns an array element by value.
*/
const nsID &operator[] (size_t aIdx) const
{
Assert(m.arr != NULL);
Assert(aIdx < size());
return m.arr[aIdx] ? *m.arr[aIdx] : *nsIDRef::Empty;
}
};
/**
* Version of com::SafeArray for const arrays of GUID.
*
* This class is used to work with input GUID array parameters in method
* implementations. See SafeGUIDArray for more details.
*/
class SafeConstGUIDArray : public SafeArray >
{
public:
typedef SafeArray > Base;
/** See SafeArray<>::SafeArray(). */
SafeConstGUIDArray() {}
/* See SafeArray<>::SafeArray(ComSafeArrayIn(T, aArg)). */
SafeConstGUIDArray(ComSafeGUIDArrayIn(aArg))
: Base(ComSafeGUIDArrayInArg(aArg)) {}
/**
* Array access operator that returns an array element by reference. As a
* special case, the return value of this operator on XPCOM is nsID (GUID)
* instead of nsID *, for compatibility with the MS COM version.
*
* The rest is equivalent to SafeArray<>::operator[].
*/
const nsID &operator[] (size_t aIdx) const
{
AssertReturn(m.arr != NULL, **((const nsID * *)NULL));
AssertReturn(aIdx < size(), **((const nsID * *)NULL));
return *m.arr[aIdx];
}
private:
/* These are disabled because of const. */
bool reset(size_t aNewSize) { NOREF(aNewSize); return false; }
};
#else /* !VBOX_WITH_XPCOM */
typedef SafeArray SafeGUIDArray;
typedef SafeArray > SafeConstGUIDArray;
#endif /* !VBOX_WITH_XPCOM */
////////////////////////////////////////////////////////////////////////////////
#ifdef VBOX_WITH_XPCOM
template
struct SafeIfaceArrayTraits
{
protected:
static void Init(I * &aElem) { aElem = NULL; }
static void Uninit(I * &aElem)
{
if (aElem)
{
aElem->Release();
aElem = NULL;
}
}
static void Copy(I * aFrom, I * &aTo)
{
if (aFrom != NULL)
{
aTo = aFrom;
aTo->AddRef();
}
else
aTo = NULL;
}
public:
/* Magic to workaround strict rules of par. 4.4.4 of the C++ standard. */
static I **__asInParam_Arr(I **aArr) { return aArr; }
static I **__asInParam_Arr(const I **aArr) { return const_cast(aArr); }
};
#else /* !VBOX_WITH_XPCOM */
template
struct SafeIfaceArrayTraits
{
protected:
static VARTYPE VarType() { return VT_DISPATCH; }
static ULONG VarCount(size_t aSize) { return (ULONG)aSize; }
static size_t Size(ULONG aVarCount) { return (size_t)aVarCount; }
static void Copy(I * aFrom, I * &aTo)
{
if (aFrom != NULL)
{
aTo = aFrom;
aTo->AddRef();
}
else
aTo = NULL;
}
static SAFEARRAY *CreateSafeArray(VARTYPE aVarType, SAFEARRAYBOUND *aBound)
{
NOREF(aVarType);
return SafeArrayCreateEx(VT_DISPATCH, 1, aBound, (PVOID)&_ATL_IIDOF(I));
}
};
#endif /* !VBOX_WITH_XPCOM */
////////////////////////////////////////////////////////////////////////////////
/**
* Version of com::SafeArray for arrays of interface pointers.
*
* Except that it manages arrays of interface pointers, the usage of this class
* is identical to com::SafeArray.
*
* @param I Interface class (no asterisk).
*/
template
class SafeIfaceArray : public SafeArray >
{
public:
typedef SafeArray > Base;
/**
* Creates a null array.
*/
SafeIfaceArray() {}
/**
* Creates a new array of the given size. All elements of the newly created
* array initialized with null values.
*
* @param aSize Initial number of elements in the array. Must be greater
* than 0.
*
* @note If this object remains null after construction it means that there
* was not enough memory for creating an array of the requested size.
* The constructor will also assert in this case.
*/
SafeIfaceArray(size_t aSize) { Base::resize(aSize); }
/**
* Weakly attaches this instance to the existing array passed in a method
* parameter declared using the ComSafeArrayIn macro. When using this call,
* always wrap the parameter name in the ComSafeArrayOutArg macro call like
* this:
*
* SafeArray safeArray(ComSafeArrayInArg(aArg));
*
*
* Note that this constructor doesn't take the ownership of the array. In
* particular, this means that operations that operate on the ownership
* (e.g. #detachTo()) are forbidden and will assert.
*
* @param aArg Input method parameter to attach to.
*/
SafeIfaceArray(ComSafeArrayIn(I *, aArg))
{
if (aArg)
{
#ifdef VBOX_WITH_XPCOM
Base::m.size = aArgSize;
Base::m.arr = aArg;
Base::m.isWeak = true;
#else /* !VBOX_WITH_XPCOM */
SAFEARRAY *arg = aArg;
AssertReturnVoid(arg->cDims == 1);
VARTYPE vt;
HRESULT rc = SafeArrayGetVartype(arg, &vt);
AssertComRCReturnVoid(rc);
AssertMsgReturnVoid(vt == VT_UNKNOWN || vt == VT_DISPATCH,
("Expected vartype VT_UNKNOWN or VT_DISPATCH, got %d.\n",
vt));
GUID guid;
rc = SafeArrayGetIID(arg, &guid);
AssertComRCReturnVoid(rc);
AssertMsgReturnVoid(InlineIsEqualGUID(_ATL_IIDOF(I), guid),
("Expected IID {%RTuuid}, got {%RTuuid}.\n",
&_ATL_IIDOF(I), &guid));
rc = SafeArrayAccessData(arg, (void HUGEP **)&m.raw);
AssertComRCReturnVoid(rc);
m.arr = arg;
m.isWeak = true;
#endif /* !VBOX_WITH_XPCOM */
}
}
/**
* Creates a deep copy of the given standard C++ container that stores
* interface pointers as objects of the ComPtr class.
*
* @param aCntr Container object to copy.
*
* @param C Standard C++ container template class (normally deduced from
* @c aCntr).
* @param A Standard C++ allocator class (deduced from @c aCntr).
* @param OI Argument to the ComPtr template (deduced from @c aCntr).
*/
template class C, class A, class OI>
SafeIfaceArray(const C, A> & aCntr)
{
typedef C, A> List;
Base::resize(aCntr.size());
AssertReturnVoid(!Base::isNull());
int i = 0;
for (typename List::const_iterator it = aCntr.begin();
it != aCntr.end(); ++ it, ++ i)
#ifdef VBOX_WITH_XPCOM
this->Copy(*it, Base::m.arr[i]);
#else
Copy(*it, Base::m.raw[i]);
#endif
}
/**
* Creates a deep copy of the given standard C++ container that stores
* interface pointers as objects of the ComObjPtr class.
*
* @param aCntr Container object to copy.
*
* @param C Standard C++ container template class (normally deduced from
* @c aCntr).
* @param A Standard C++ allocator class (deduced from @c aCntr).
* @param OI Argument to the ComObjPtr template (deduced from @c aCntr).
*/
template class C, class A, class OI>
SafeIfaceArray(const C, A> & aCntr)
{
typedef C, A> List;
Base::resize(aCntr.size());
AssertReturnVoid(!Base::isNull());
int i = 0;
for (typename List::const_iterator it = aCntr.begin();
it != aCntr.end(); ++ it, ++ i)
#ifdef VBOX_WITH_XPCOM
SafeIfaceArray::Copy(*it, Base::m.arr[i]);
#else
Copy(*it, Base::m.raw[i]);
#endif
}
/**
* Creates a deep copy of the given standard C++ map whose values are
* interface pointers stored as objects of the ComPtr class.
*
* @param aMap Map object to copy.
*
* @param C Standard C++ map template class (normally deduced from
* @c aCntr).
* @param L Standard C++ compare class (deduced from @c aCntr).
* @param A Standard C++ allocator class (deduced from @c aCntr).
* @param K Map key class (deduced from @c aCntr).
* @param OI Argument to the ComPtr template (deduced from @c aCntr).
*/
template
class C, class L, class A, class K, class OI>
SafeIfaceArray(const C, L, A> & aMap)
{
typedef C, L, A> Map;
Base::resize(aMap.size());
AssertReturnVoid(!Base::isNull());
int i = 0;
for (typename Map::const_iterator it = aMap.begin();
it != aMap.end(); ++ it, ++ i)
#ifdef VBOX_WITH_XPCOM
SafeIfaceArray::Copy(it->second, Base::m.arr[i]);
#else
Copy(it->second, Base::m.raw[i]);
#endif
}
/**
* Creates a deep copy of the given standard C++ map whose values are
* interface pointers stored as objects of the ComObjPtr class.
*
* @param aMap Map object to copy.
*
* @param C Standard C++ map template class (normally deduced from
* @c aCntr).
* @param L Standard C++ compare class (deduced from @c aCntr).
* @param A Standard C++ allocator class (deduced from @c aCntr).
* @param K Map key class (deduced from @c aCntr).
* @param OI Argument to the ComObjPtr template (deduced from @c aCntr).
*/
template
class C, class L, class A, class K, class OI>
SafeIfaceArray(const C, L, A> & aMap)
{
typedef C, L, A> Map;
Base::resize(aMap.size());
AssertReturnVoid(!Base::isNull());
int i = 0;
for (typename Map::const_iterator it = aMap.begin();
it != aMap.end(); ++ it, ++ i)
#ifdef VBOX_WITH_XPCOM
SafeIfaceArray::Copy(it->second, Base::m.arr[i]);
#else
Copy(it->second, Base::m.raw[i]);
#endif
}
void setElement(size_t iIdx, I* obj)
{
#ifdef VBOX_WITH_XPCOM
SafeIfaceArray::Copy(obj, Base::m.arr[iIdx]);
#else
Copy(obj, Base::m.raw[iIdx]);
#endif
}
};
} /* namespace com */
/** @} */
#endif /* !___VBox_com_array_h */