blob: e28d31df7fac4ec2f8ac0b6ea66166541a6a4fb0 [file] [log] [blame]
; AutoExp.Dat - templates for automatically expanding data
; Copyright(c) Microsoft Corporation. All Rights Reserved.
;---------------------------------------------------------------
;
; While debugging, Data Tips and items in the Watch and Variable
; windows are automatically expanded to show their most important
; elements. The expansion follows the format given by the rules
; in this file. You can add rules for your types or change the
; predefined rules.
;
; For good examples, read the rules in this file.
;
; To find what the debugger considers the type of a variable to
; be, add it to the Watch window and look at the Type column.
;
; An AutoExpand rule is a line with the name of a type, an equals
; sign, and text with replaceable parts in angle brackets. The
; part in angle brackets names a member of the type and an
; optional Watch format specifier.
;
; AutoExpand rules use the following syntax. The equals sign (=),
; angle brackets (<>), and comma are taken literally. Square
; brackets ([]) indicate optional items.
;
; type=[text]<member[,format]>...
;
; type Name of the type (may be followed by <*> for template
; types such as the ATL types listed below).
;
; text Any text.Usually the name of the member to display,
; or a shorthand name for the member.
;
; member Name of a member to display.
;
; format Watch format specifier. One of the following:
;
; Letter Description Sample Display
; ------ -------------------------- ------------ -------------
; d,i Signed decimal integer 0xF000F065,d -268373915
; u Unsigned decimal integer 0x0065,u 101
; o Unsigned octal integer 0xF065,o 0170145
; x,X Hexadecimal integer 61541,X 0X0000F065
; l,h long or short prefix for 00406042,hx 0x0c22
; d, i, u, o, x, X
; f Signed floating-point 3./2.,f 1.500000
; e Signed scientific-notation 3./2.,e 1.500000e+000
; g Shorter of e and f 3./2.,g 1.5
; c Single character 0x0065,c 'e'
; s Zero-terminated string pVar,s "Hello world"
; su Unicode string pVar,su "Hello world"
;
; For details of other format specifiers see Help under:
; "format specifiers/watch variable"
;
; The special format <,t> specifies the name of the most-derived
; type of the object. This is especially useful with pointers or
; references to a base class.
;
; If there is no rule for a class, the base classes are checked for
; a matching rule.
;
; There are some special entries allowed in the AutoExpand section:
; $BUILTIN is used to display more complex types that need to do more
; than just show a member variable or two.
; $ADDIN allows external DLLs to be added to display even more complex
; types via the EE Add-in API. The first argument is the DLL name, the
; second argument is the name of the export from the DLL to use. For
; further information on this API see the sample called EEAddIn.
;
; WARNING: if hexadecimal mode is on in the watch window, all numbers here are
; evaluated in hex, e.g. 42 becomes 0x42
[AutoExpand]
; from windef.h
tagPOINT =x=<x> y=<y>
tagRECT =top=<top> bottom=<bottom> left=<left> right=<right>
; from winuser.h
tagMSG =msg=<message,x> wp=<wParam,x> lp=<lParam,x>
; intrinsics
__m64 =<m64_i64,x>
__m128=$BUILTIN(M128)
__m128i=$BUILTIN(M128I)
__m128d=$BUILTIN(M128D)
; from afxwin.h
CDC =hDC=<m_hDC> attrib=<m_hAttribDC>
CPaintDC =<,t> hWnd=<m_hWnd>
CPoint =x=<x> y=<y>
CRect =top=<top> bottom=<bottom> left=<left> right=<right>
CSize =cx=<cx> cy=<cy>
CWnd =<,t> hWnd=<m_hWnd>
CWinApp =<,t> <m_pszAppName,s>
CWinThread =<,t> h=<m_hThread> proc=<m_pfnThreadProc>
; from afxcoll.h
CPtrList =cnt=<m_nCount>
; from afxstat_.h
CProcessLocalObject =<,t>
CThreadLocalObject =<,t>
; from afx.h
CArchiveException =cause=<m_cause>
CFile =hFile=<m_hFile> name=<m_strFileName.m_pchData,s>
CFileException =cause=<m_cause> OS Error=m_lOsError
CMemFile =pos=<m_nPosition> size=<m_nFileSize>
CObject =<,t>
CRuntimeClass =<m_lpszClassName,s>
CStdioFile =FILE*=<m_pStream> name=<m_strFilename.m_pchData,s>
CTimeSpan =time=<m_time>
CTime =time=<m_time>
; from afxcoll.h
CByteArray =count=<m_nCount>
CStringList =count=<m_nCount>
; same for all CXXXArray classes
; same for CXXXList
; same for CMapXXToXX
; various string classes from MFC & ATL
_com_error=<m_hresult,hr>
_bstr_t=<m_Data->m_wstr,su> (<m_Data->m_RefCount,u>)
_com_ptr_t<*>=<m_pInterface>
_LARGE_INTEGER=<QuadPart>
_ULARGE_INTEGER=<QuadPart>
ATL::CComPtr<*>=<p>
ATL::CComQIPtr<*>=<p>
tagVARIANT=$BUILTIN(VARIANT)
VARIANT=$BUILTIN(VARIANT)
_GUID=$BUILTIN(GUID)
; see EEAddIn sample for how to use these
;_SYSTEMTIME=$ADDIN(EEAddIn.dll,AddIn_SystemTime)
;_FILETIME=$ADDIN(EEAddIn.dll,AddIn_FileTime)
[Visualizer]
; This section contains visualizers for STL and ATL containers
; DO NOT MODIFY
ATL::CStringT<char,*>|CSimpleStringT<char,*>|ATL::CSimpleStringT<char,*>{
preview ([$e.m_pszData,s])
stringview ([$e.m_pszData,sb])
}
ATL::CStringT<wchar_t,*>|CSimpleStringT<wchar_t,*>|ATL::CSimpleStringT<wchar_t,*>|ATL::CStringT<unsigned short,*>|CSimpleStringT<unsigned short,*>|ATL::CSimpleStringT<unsigned short,*>{
preview ([$e.m_pszData,su])
stringview ([$e.m_pszData,sub])
}
ATL::CComBSTR{
preview ([$e.m_str,su])
stringview ([$e.m_str,sub])
}
; Many visualizers use nested #()s.
; Why not use #(foo, bar) instead of #(#(foo), #(bar))?
; The former alphabetically sorts its fields, while the latter does not.
;------------------------------------------------------------------------------
; std::pair from <utility>
;------------------------------------------------------------------------------
std::pair<*>{
; pair is previewed with "(<first>, <second>)".
preview (
#(
"(",
$e.first,
", ",
$e.second,
")"
)
)
; We gloss over the fact that first and second are actually stored in _Pair_base.
children (
#(
#(first : $e.first),
#(second : $e.second)
)
)
}
;------------------------------------------------------------------------------
; std::plus, etc. from <functional>
;------------------------------------------------------------------------------
; STL functors are previewed with their names.
; They have no state, so they have no children.
std::plus<*>{
preview ( "plus" )
children ( #array(expr: 0, size: 0) )
}
std::minus<*>{
preview ( "minus" )
children ( #array(expr: 0, size: 0) )
}
std::multiplies<*>{
preview ( "multiplies" )
children ( #array(expr: 0, size: 0) )
}
std::divides<*>{
preview ( "divides" )
children ( #array(expr: 0, size: 0) )
}
std::modulus<*>{
preview ( "modulus" )
children ( #array(expr: 0, size: 0) )
}
std::negate<*>{
preview ( "negate" )
children ( #array(expr: 0, size: 0) )
}
std::equal_to<*>{
preview ( "equal_to" )
children ( #array(expr: 0, size: 0) )
}
std::not_equal_to<*>{
preview ( "not_equal_to" )
children ( #array(expr: 0, size: 0) )
}
std::greater<*>{
preview ( "greater" )
children ( #array(expr: 0, size: 0) )
}
std::less<*>{
preview ( "less" )
children ( #array(expr: 0, size: 0) )
}
std::greater_equal<*>{
preview ( "greater_equal" )
children ( #array(expr: 0, size: 0) )
}
std::less_equal<*>{
preview ( "less_equal" )
children ( #array(expr: 0, size: 0) )
}
std::logical_and<*>{
preview ( "logical_and" )
children ( #array(expr: 0, size: 0) )
}
std::logical_or<*>{
preview ( "logical_or" )
children ( #array(expr: 0, size: 0) )
}
std::logical_not<*>{
preview ( "logical_not" )
children ( #array(expr: 0, size: 0) )
}
;------------------------------------------------------------------------------
; std::not1() from <functional>
; std::not2() from <functional>
;------------------------------------------------------------------------------
; STL negators are previewed with "not[12](<stored functor>)".
; They have a child with the fake name of [pred], so that the
; stored functor can be inspected.
std::unary_negate<*>{
preview (
#(
"not1(",
$e._Functor,
")"
)
)
children (
#([pred] : $e._Functor)
)
}
std::binary_negate<*>{
preview (
#(
"not2(",
$e._Functor,
")"
)
)
children (
#([pred] : $e._Functor)
)
}
;------------------------------------------------------------------------------
; std::bind1st() from <functional>
; std::bind2nd() from <functional>
;------------------------------------------------------------------------------
; STL binders are previewed with "bind1st(<op>, <value>)" or "bind2nd(<op>, <value>)".
; We gloss over the fact that they derive from unary_function.
std::binder1st<*>{
preview (
#(
"bind1st(",
$e.op,
", ",
$e.value,
")"
)
)
children (
#(
#(op : $e.op),
#(value : $e.value)
)
)
}
std::binder2nd<*>{
preview (
#(
"bind2nd(",
$e.op,
", ",
$e.value,
")"
)
)
children (
#(
#(op : $e.op),
#(value : $e.value)
)
)
}
;------------------------------------------------------------------------------
; std::ptr_fun() from <functional>
;------------------------------------------------------------------------------
; STL function pointer adaptors are previewed with "ptr_fun(<stored function pointer>)".
; Function pointers have no children, so the adaptors have no children.
std::pointer_to_unary_function<*>|std::pointer_to_binary_function<*>{
preview (
#(
"ptr_fun(",
$e._Pfun,
")"
)
)
children ( #array(expr: 0, size: 0) )
}
;------------------------------------------------------------------------------
; std::mem_fun() from <functional>
; std::mem_fun_ref() from <functional>
;------------------------------------------------------------------------------
; See ptr_fun().
std::mem_fun_t<*>|std::mem_fun1_t<*>|std::const_mem_fun_t<*>|std::const_mem_fun1_t<*>{
preview (
#(
"mem_fun(",
$e._Pmemfun,
")"
)
)
children ( #array(expr: 0, size: 0) )
}
std::mem_fun_ref_t<*>|std::mem_fun1_ref_t<*>|std::const_mem_fun_ref_t<*>|std::const_mem_fun1_ref_t<*>{
preview (
#(
"mem_fun_ref(",
$e._Pmemfun,
")"
)
)
children ( #array(expr: 0, size: 0) )
}
;------------------------------------------------------------------------------
; std::auto_ptr from <memory>
;------------------------------------------------------------------------------
std::auto_ptr<*>{
; An empty auto_ptr is previewed with "empty".
; Otherwise, it is previewed with "auto_ptr <object>".
preview (
#if ($e._Myptr == 0) (
"empty"
) #else (
#(
"auto_ptr ",
*$e._Myptr
)
)
)
; An empty auto_ptr has no children.
; Otherwise, it has a single child, its stored pointer, with a fake name of [ptr].
children (
#if ($e._Myptr == 0) (
#array(expr: 0, size: 0)
) #else (
#([ptr] : $e._Myptr)
)
)
}
;------------------------------------------------------------------------------
; std::basic_string from <string>
;------------------------------------------------------------------------------
; basic_string is previewed with its stored string.
; It has [size] and [capacity] children, followed by [0], [1], [2], etc. children
; displaying its stored characters.
; The ($e._Myres) < ($e._BUF_SIZE) test determines whether the Small String Optimization
; is in effect.
; NOTE: The parentheses in ($e._Myres) < ($e._BUF_SIZE) are necessary.
std::basic_string<char,*>{
preview ( #if (($e._Myres) < ($e._BUF_SIZE)) ( [$e._Bx._Buf,s] ) #else ( [$e._Bx._Ptr,s] ))
stringview ( #if (($e._Myres) < ($e._BUF_SIZE)) ( [$e._Bx._Buf,sb] ) #else ( [$e._Bx._Ptr,sb] ))
children (
#(
#([size] : $e._Mysize),
#([capacity] : $e._Myres),
#if (($e._Myres) < ($e._BUF_SIZE)) (
#array(expr: $e._Bx._Buf[$i], size: $e._Mysize)
) #else (
#array(expr: $e._Bx._Ptr[$i], size: $e._Mysize)
)
)
)
}
std::basic_string<unsigned short,*>|std::basic_string<wchar_t,*>{
preview ( #if (($e._Myres) < ($e._BUF_SIZE)) ( [$e._Bx._Buf,su] ) #else ( [$e._Bx._Ptr,su] ))
stringview ( #if (($e._Myres) < ($e._BUF_SIZE)) ( [$e._Bx._Buf,sub] ) #else ( [$e._Bx._Ptr,sub] ))
children (
#(
#([size] : $e._Mysize),
#([capacity] : $e._Myres),
#if (($e._Myres) < ($e._BUF_SIZE)) (
#array(expr: $e._Bx._Buf[$i], size: $e._Mysize)
) #else (
#array(expr: $e._Bx._Ptr[$i], size: $e._Mysize)
)
)
)
}
std::_String_iterator<char,*>|std::_String_const_iterator<char,*>{
preview ( [$e._Ptr,s] )
stringview ( [$e._Ptr,sb] )
children ( #([ptr] : $e._Ptr) )
}
std::_String_iterator<unsigned short,*>|std::_String_const_iterator<unsigned short,*>|std::_String_iterator<wchar_t,*>|std::_String_const_iterator<wchar_t,*>{
preview ( [$e._Ptr,su] )
stringview ( [$e._Ptr,sub] )
children ( #([ptr] : $e._Ptr) )
}
;------------------------------------------------------------------------------
; std::vector<bool> from <vector>
;------------------------------------------------------------------------------
; Despite its packed representation, vector<bool> is visualized like vector<T>.
std::vector<bool,*>{
preview (
#(
"[",
$e._Mysize,
"](",
#array(
expr: (bool)(($e._Myvec._Myfirst[$i / _VBITS] >> ($i % _VBITS)) & 1),
size: $e._Mysize
),
")"
)
)
children (
#(
#([size] : $e._Mysize),
#([capacity] : ($e._Myvec._Myend - $e._Myvec._Myfirst) * _VBITS),
#array(
expr: (bool)(($e._Myvec._Myfirst[$i / _VBITS] >> ($i % _VBITS)) & 1),
size: $e._Mysize
)
)
)
}
std::_Vb_reference<*>|std::_Vb_iterator<*>|std::_Vb_const_iterator<*>{
preview (
(bool)((*$e._Myptr >> $e._Myoff) & 1)
)
children (
#(
#([ptr] : $e._Myptr),
#([offset] : $e._Myoff)
)
)
}
;------------------------------------------------------------------------------
; std::vector from <vector>
;------------------------------------------------------------------------------
; vector is previewed with "[<size>](<elements>)".
; It has [size] and [capacity] children, followed by its elements.
; The other containers follow its example.
std::vector<*>{
preview (
#(
"[",
$e._Mylast - $e._Myfirst,
"](",
#array(
expr: $e._Myfirst[$i],
size: $e._Mylast - $e._Myfirst
),
")"
)
)
children (
#(
#([size] : $e._Mylast - $e._Myfirst),
#([capacity] : $e._Myend - $e._Myfirst),
#array(
expr: $e._Myfirst[$i],
size: $e._Mylast - $e._Myfirst
)
)
)
}
std::_Vector_iterator<*>|std::_Vector_const_iterator<*>{
preview (
*$e._Ptr
)
children (
#([ptr] : $e._Ptr)
)
}
;------------------------------------------------------------------------------
; std::deque from <deque>
;------------------------------------------------------------------------------
std::deque<*>{
preview (
#(
"[",
$e._Mysize,
"](",
#array(
expr: $e._Map[(($i + $e._Myoff) / $e._EEN_DS) % $e._Mapsize][($i + $e._Myoff) % $e._EEN_DS],
size: $e._Mysize
),
")"
)
)
children (
#(
#array(
expr: $e._Map[(($i + $e._Myoff) / $e._EEN_DS) % $e._Mapsize][($i + $e._Myoff) % $e._EEN_DS],
size: $e._Mysize
)
)
)
}
std::_Deque_iterator<*,*>|std::_Deque_const_iterator<*,*>{
preview (
#if ($e._Myoff >= ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Myoff + ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Mysize) (
"end"
) #else (
((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Map[($e._Myoff / ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_EEN_DS) % ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Mapsize][$e._Myoff % ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_EEN_DS]
)
)
children (
#if ($e._Myoff >= ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Myoff + ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Mysize) (
#array(expr: 0, size: 0)
) #else (
#(
#([index] : $e._Myoff - ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Myoff),
#([ptr] : &((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Map[($e._Myoff / ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_EEN_DS) % ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_Mapsize][$e._Myoff % ((std::deque<$T1,$T2> *)$e._Myproxy->_Mycont)->_EEN_DS] )
)
)
)
}
;------------------------------------------------------------------------------
; std::list from <list>
;------------------------------------------------------------------------------
std::list<*>{
preview (
#(
"[",
$e._Mysize,
"](",
#list(
head: $e._Myhead->_Next,
size: $e._Mysize,
next: _Next
) : $e._Myval,
")"
)
)
children (
#list(
head: $e._Myhead->_Next,
size: $e._Mysize,
next: _Next
) : $e._Myval
)
}
std::_List_iterator<*>|std::_List_const_iterator<*>{
preview ( $e._Ptr->_Myval )
children ( #([ptr] : &$e._Ptr->_Myval) )
}
;------------------------------------------------------------------------------
; std::queue from <queue>
; std::stack from <stack>
;------------------------------------------------------------------------------
std::queue<*>|std::stack<*>{
preview ( $e.c )
children ( #(c : $e.c) )
}
;------------------------------------------------------------------------------
; std::priority_queue from <queue>
;------------------------------------------------------------------------------
std::priority_queue<*>{
preview ( $e.c )
children (
#(
#(c [heap]: $e.c),
#(comp : $e.comp)
)
)
}
;------------------------------------------------------------------------------
; std::map from <map>
; std::multimap from <map>
; std::set from <set>
; std::multiset from <set>
;------------------------------------------------------------------------------
std::map<*>|std::multimap<*>|std::set<*>|std::multiset<*>{
preview (
#(
"[",
$e._Mysize,
"](",
#tree(
head: $e._Myhead->_Parent,
skip: $e._Myhead,
left: _Left,
right: _Right,
size: $e._Mysize
) : $e._Myval,
")"
)
)
children (
#(
#([comp] : $e.comp),
#tree(
head: $e._Myhead->_Parent,
skip: $e._Myhead,
left: _Left,
right: _Right,
size: $e._Mysize
) : $e._Myval
)
)
}
std::_Tree_iterator<*>|std::_Tree_const_iterator<*>{
preview ( $e._Ptr->_Myval )
children ( #([ptr] : &$e._Ptr->_Myval) )
}
;------------------------------------------------------------------------------
; std::bitset from <bitset>
;------------------------------------------------------------------------------
std::bitset<*>{
preview (
#(
"[",
$e._EEN_BITS,
"](",
#array(
expr: [($e._Array[$i / $e._Bitsperword] >> ($i % $e._Bitsperword)) & 1,d],
size: $e._EEN_BITS
),
")"
)
)
children (
#array(
expr: [($e._Array[$i / $e._Bitsperword] >> ($i % $e._Bitsperword)) & 1,d],
size: $e._EEN_BITS
)
)
}
std::bitset<*>::reference{
preview (
[($e._Pbitset->_Array[$i / $e._Pbitset->_Bitsperword] >> ($e._Mypos % $e._Pbitset->_Bitsperword)) & 1,d]
)
children (
#(
#([bitset] : $e._Pbitset),
#([pos] : $e._Mypos)
)
)
}
;------------------------------------------------------------------------------
; std::reverse_iterator from <iterator>
;------------------------------------------------------------------------------
std::reverse_iterator<std::_String_iterator<*> >|std::reverse_iterator<std::_String_const_iterator<*> >{
preview (
#(
"reverse_iterator to ",
$e.current._Ptr[-1]
)
)
children (
#(
#([to] : $e.current._Ptr - 1),
#(current : $e.current)
)
)
}
std::reverse_iterator<std::_Vb_iterator<*> >|std::reverse_iterator<std::_Vb_const_iterator<*> >{
preview (
#(
"reverse_iterator to ",
#if ($e.current._Myoff != 0) (
(bool)((*$e.current._Myptr >> ($e.current._Myoff - 1)) & 1)
) #else (
(bool)(($e.current._Myptr[-1] >> (_VBITS - 1)) & 1)
)
)
)
children (
#if ($e.current._Myoff != 0) (
#(
#([to ptr] : $e.current._Myptr),
#([to offset] : $e.current._Myoff - 1),
#(current : $e.current)
)
) #else (
#(
#([to ptr] : $e.current._Myptr - 1),
#([to offset] : _VBITS - 1),
#(current : $e.current)
)
)
)
}
std::reverse_iterator<std::_Vector_iterator<*> >|std::reverse_iterator<std::_Vector_const_iterator<*> >{
preview (
#(
"reverse_iterator to ",
$e.current._Ptr[-1]
)
)
children (
#(
#([to] : $e.current._Ptr - 1),
#(current : $e.current)
)
)
}
std::reverse_iterator<std::_Deque_iterator<*,*> >|std::reverse_iterator<std::_Deque_const_iterator<*,*> >{
preview (
#(
"reverse_iterator to ",
#if ($e.current._Myoff == ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Myoff) (
"end"
) #else (
((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Map[(($e.current._Myoff - 1) / ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_EEN_DS) % ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Mapsize][($e.current._Myoff - 1) % ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_EEN_DS]
)
)
)
children (
#if ($e.current._Myoff == ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Myoff) (
#(current : $e.current)
) #else (
#(
#([to index] : ($e.current._Myoff - 1) - ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Myoff),
#([to ptr] : &((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Map[(($e.current._Myoff - 1) / ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_EEN_DS) % ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_Mapsize][($e.current._Myoff - 1) % ((std::deque<$T1,$T2> *)$e.current._Myproxy->_Mycont)->_EEN_DS] ),
#(current : $e.current)
)
)
)
}
std::reverse_iterator<std::_List_iterator<*> >|std::reverse_iterator<std::_List_const_iterator<*> >{
preview (
#(
"reverse_iterator to ",
$e.current._Ptr->_Prev->_Myval
)
)
children (
#(
#([to] : &$e.current._Ptr->_Prev->_Myval),
#(current : $e.current)
)
)
}
std::reverse_iterator<std::_Array_iterator<*> >|std::reverse_iterator<std::_Array_const_iterator<*> >{
preview (
#(
"reverse_iterator to ",
#if ($e.current._EEN_IDL == 0) (
$e.current._Ptr[-1]
) #else (
#if ($e.current._Idx == 0) (
"end"
) #else (
$e.current._Ptr[$e.current._Idx - 1]
)
)
)
)
children (
#if ($e.current._EEN_IDL == 0) (
#(
#([to] : $e.current._Ptr - 1),
#(current : $e.current)
)
) #else (
#if ($e.current._Idx == 0) (
#(current : $e.current)
) #else (
#(
#([to] : $e.current._Ptr + $e.current._Idx - 1),
#(current : $e.current)
)
)
)
)
}
std::reverse_iterator<*>{
preview (
#(
"reverse_iterator current ",
$e.current
)
)
children (
#(current : $e.current)
)
}
;------------------------------------------------------------------------------
; std::complex from <complex>
;------------------------------------------------------------------------------
std::complex<*>{
preview (
#if ($e._Val[1] == 0) (
; Purely real.
$e._Val[0]
) #else (
#if ($e._Val[0] == 0) (
; Purely imaginary.
#if ($e._Val[1] < 0) (
#("-i*", -$e._Val[1])
) #else (
#("i*", $e._Val[1])
)
) #else (
; Mixed.
#if ($e._Val[1] < 0) (
#($e._Val[0], "-i*", -$e._Val[1])
) #else (
#($e._Val[0], "+i*", $e._Val[1])
)
)
)
)
children (
#(
#(real : $e._Val[0]),
#(imag : $e._Val[1])
)
)
}
;------------------------------------------------------------------------------
; std::valarray from <valarray>
;------------------------------------------------------------------------------
std::valarray<*>{
preview (
#(
"[",
$e._Mysize,
"](",
#array(
expr: $e._Myptr[$i],
size: $e._Mysize
),
")"
)
)
children (
#array(
expr: $e._Myptr[$i],
size: $e._Mysize
)
)
}
;------------------------------------------------------------------------------
; std::tr1::reference_wrapper from <functional>
;------------------------------------------------------------------------------
std::tr1::reference_wrapper<*>{
preview (
#if ($e._Callee._EEN_INDIRECT == 1) (
; For ordinary T, reference_wrapper<T> stores a T * _Callee._Ptr
; which is non-null. Actual references are previewed with what they
; refer to, so reference_wrapper<T> is previewed with dereferencing its
; stored pointer.
*$e._Callee._Ptr
) #else (
; When T is a pointer to data member type, reference_wrapper<T>
; stores a T _Callee._Object directly.
$e._Callee._Object
)
)
children (
#if ($e._Callee._EEN_INDIRECT == 1) (
; Actual references have the same children as what they refer to.
; Unfortunately, there appears to be no way to imitate this exactly.
; Therefore, we make reference_wrapper<T> appear to have a single
; child, its stored pointer, with a fake name of [ptr].
#([ptr] : $e._Callee._Ptr)
) #else (
; When T is a pointer to data member type, T has no children,
; so we make reference_wrapper<T> appear to have no children.
#array(expr: 0, size: 0)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::shared_ptr from <memory>
;------------------------------------------------------------------------------
std::tr1::_Ref_count<*>{
preview ( "default" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ref_count_del<*>{
preview ( "custom deleter" )
children ( #([deleter] : $e._Dtor) )
}
std::tr1::_Ref_count_del_alloc<*>{
preview ( "custom deleter, custom allocator" )
children (
#(
#([deleter] : $e._Dtor),
#([allocator] : $e._Myal)
)
)
}
std::tr1::_Ref_count_obj<*>{
preview ( "make_shared" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ref_count_obj_alloc<*>{
preview ( "allocate_shared" )
children ( #([allocator] : $e._Myal) )
}
std::tr1::shared_ptr<*>{
preview (
; shared_ptr<T> stores a T * _Ptr .
#if ($e._Ptr == 0) (
; A default-constructed shared_ptr has a null _Ptr and a null _Rep,
; and is formally said to be empty.
; A shared_ptr constructed from a null pointer has a null _Ptr
; and a NON-null _Rep . It is formally said to own the null pointer.
; We preview both with "empty".
"empty"
) #else (
; Raw pointers are previewed with "<pointer value> <object>".
; auto_ptr is previewed with "auto_ptr <object>".
; Following these examples, shared_ptr is previewed with
; "shared_ptr <object> [N strong refs, M weak refs]".
#(
"shared_ptr ",
*$e._Ptr,
" [",
$e._Rep->_Uses,
#if ($e._Rep->_Uses == 1) (" strong ref") #else (" strong refs"),
#if ($e._Rep->_Weaks - 1 > 0) (
#(
", ",
$e._Rep->_Weaks - 1,
#if ($e._Rep->_Weaks - 1 == 1) (" weak ref") #else (" weak refs")
)
),
"] [",
*$e._Rep,
"]"
)
; Note: _Rep->_Uses counts how many shared_ptrs share ownership of the object,
; so we directly display it as the strong reference count.
; _Rep->_Weaks counts how many shared_ptrs and weak_ptrs share ownership of
; the "representation object" (or "control block"). All of the shared_ptrs are
; counted as a single owner. That is, _Weaks is initialized to 1, and when
; _Uses falls to 0, _Weaks is decremented. This avoids incrementing and decrementing
; _Weaks every time that a shared_ptr gains or loses ownership. Therefore,
; _Weaks - 1 is the weak reference count, the number of weak_ptrs that are observing
; the shared object.
)
)
children (
#if ($e._Ptr == 0) (
; We make empty shared_ptrs (and shared_ptrs that own
; the null pointer) appear to have no children.
#array(expr: 0, size: 0)
) #else (
#(
; We make shared_ptr appear to have two children:
; Its stored pointer, with a fake name of [ptr].
#([ptr] : $e._Ptr),
; Its deleter and allocator, which may be default or custom.
#([deleter and allocator] : *$e._Rep)
)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::weak_ptr from <memory>
;------------------------------------------------------------------------------
std::tr1::weak_ptr<*>{
preview (
#if ($e._Ptr == 0) (
"empty"
) #elif ($e._Rep->_Uses == 0) (
; weak_ptr is just like shared_ptr, except that a weak_ptr can be expired.
#(
"expired [",
*$e._Rep,
"]"
)
) #else (
#(
"weak_ptr ",
*$e._Ptr,
" [",
$e._Rep->_Uses,
#if ($e._Rep->_Uses == 1) (" strong ref") #else (" strong refs"),
#if ($e._Rep->_Weaks - 1 > 0) (
#(
", ",
$e._Rep->_Weaks - 1,
#if ($e._Rep->_Weaks - 1 == 1) (" weak ref") #else (" weak refs")
)
),
"] [",
*$e._Rep,
"]"
)
)
)
children (
#if ($e._Ptr == 0) (
#array(expr: 0, size: 0)
) #elif ($e._Rep->_Uses == 0) (
; When a weak_ptr is expired, we show its deleter and allocator.
; The deleter has already been used, but the control block has not yet been deallocated.
#([deleter and allocator] : *$e._Rep)
) #else (
#(
#([ptr] : $e._Ptr),
#([deleter and allocator] : *$e._Rep)
)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::mem_fn() from <functional>
;------------------------------------------------------------------------------
; Note that when mem_fn() is given a data member pointer, it returns a _Call_wrapper<_Callable_pmd<*> > .
; Data member pointers themselves don't have useful previews, so we don't attempt to visualize this.
; When mem_fn() is given a member function pointer, it returns a _Mem_fn[N], which we can visualize.
std::tr1::_Mem_fn1<*>|std::tr1::_Mem_fn2<*>|std::tr1::_Mem_fn3<*>|std::tr1::_Mem_fn4<*>|std::tr1::_Mem_fn5<*>|std::tr1::_Mem_fn6<*>|std::tr1::_Mem_fn7<*>|std::tr1::_Mem_fn8<*>|std::tr1::_Mem_fn9<*>|std::tr1::_Mem_fn10<*>{
preview (
; We preview the functor returned by mem_fn() with "mem_fn(<stored member function pointer>)".
#(
"mem_fn(",
$e._Callee._Object,
")"
)
)
children (
; Member function pointers have no children.
#array(expr: 0, size: 0)
)
}
;------------------------------------------------------------------------------
; std::tr1::bind() from <functional>
;------------------------------------------------------------------------------
; bind() placeholders are previewed with their names.
; They have no state, so they have no children.
std::tr1::_Ph<1>{
preview ( "_1" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<2>{
preview ( "_2" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<3>{
preview ( "_3" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<4>{
preview ( "_4" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<5>{
preview ( "_5" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<6>{
preview ( "_6" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<7>{
preview ( "_7" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<8>{
preview ( "_8" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<9>{
preview ( "_9" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::_Ph<10>{
preview ( "_10" )
children ( #array(expr: 0, size: 0) )
}
; The functor returned by bind(f, t1, t2) is previewed with "bind(f, t1, t2)".
; It has children with the fake names of [f], [t1], [t2], etc.
std::tr1::_Bind<*,*,std::tr1::_Bind0<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind0<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind1<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind1<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind2<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind2<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind3<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind3<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind4<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind4<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind5<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind5<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind6<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind6<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
", ", $e._Bx._Vx5,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4),
#([t6] : $e._Bx._Vx5)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind7<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind7<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
", ", $e._Bx._Vx5,
", ", $e._Bx._Vx6,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4),
#([t6] : $e._Bx._Vx5),
#([t7] : $e._Bx._Vx6)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind8<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind8<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
", ", $e._Bx._Vx5,
", ", $e._Bx._Vx6,
", ", $e._Bx._Vx7,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4),
#([t6] : $e._Bx._Vx5),
#([t7] : $e._Bx._Vx6),
#([t8] : $e._Bx._Vx7)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind9<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind9<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
", ", $e._Bx._Vx5,
", ", $e._Bx._Vx6,
", ", $e._Bx._Vx7,
", ", $e._Bx._Vx8,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4),
#([t6] : $e._Bx._Vx5),
#([t7] : $e._Bx._Vx6),
#([t8] : $e._Bx._Vx7),
#([t9] : $e._Bx._Vx8)
)
)
}
std::tr1::_Bind<*,*,std::tr1::_Bind10<*> >|std::tr1::_Bind_fty<*,*,std::tr1::_Bind10<*> >{
preview (
#(
"bind(", $e._Bx._Callee._Object,
", ", $e._Bx._Vx0,
", ", $e._Bx._Vx1,
", ", $e._Bx._Vx2,
", ", $e._Bx._Vx3,
", ", $e._Bx._Vx4,
", ", $e._Bx._Vx5,
", ", $e._Bx._Vx6,
", ", $e._Bx._Vx7,
", ", $e._Bx._Vx8,
", ", $e._Bx._Vx9,
")"
)
)
children (
#(
#([f] : $e._Bx._Callee._Object),
#([t1] : $e._Bx._Vx0),
#([t2] : $e._Bx._Vx1),
#([t3] : $e._Bx._Vx2),
#([t4] : $e._Bx._Vx3),
#([t5] : $e._Bx._Vx4),
#([t6] : $e._Bx._Vx5),
#([t7] : $e._Bx._Vx6),
#([t8] : $e._Bx._Vx7),
#([t9] : $e._Bx._Vx8),
#([t10] : $e._Bx._Vx9)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::function from <functional>
;------------------------------------------------------------------------------
std::tr1::_Impl_no_alloc0<*>|std::tr1::_Impl_no_alloc1<*>|std::tr1::_Impl_no_alloc2<*>|std::tr1::_Impl_no_alloc3<*>|std::tr1::_Impl_no_alloc4<*>|std::tr1::_Impl_no_alloc5<*>|std::tr1::_Impl_no_alloc6<*>|std::tr1::_Impl_no_alloc7<*>|std::tr1::_Impl_no_alloc8<*>|std::tr1::_Impl_no_alloc9<*>|std::tr1::_Impl_no_alloc10<*>{
preview ( $e._Callee._Object )
children ( #([functor] : $e._Callee._Object) )
}
std::tr1::_Impl0<*>|std::tr1::_Impl1<*>|std::tr1::_Impl2<*>|std::tr1::_Impl3<*>|std::tr1::_Impl4<*>|std::tr1::_Impl5<*>|std::tr1::_Impl6<*>|std::tr1::_Impl7<*>|std::tr1::_Impl8<*>|std::tr1::_Impl9<*>|std::tr1::_Impl10<*>{
preview ( $e._Callee._Object )
children (
#(
#([functor] : $e._Callee._Object),
#([allocator] : $e._Myal)
)
)
}
std::tr1::function<*>{
preview (
#if ($e._Impl == 0) (
; Detecting empty functions is trivial.
"empty"
) #else (
*$e._Impl
)
)
children (
#if ($e._Impl == 0) (
; We make empty functions appear to have no children.
#array(expr: 0, size: 0)
) #else (
#([functor and allocator] : *$e._Impl)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::tuple from <tuple>
;------------------------------------------------------------------------------
; tuple is visualized like pair, except that we have to give fake names to tuple's children.
std::tr1::tuple<std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
"()"
)
children (
#array(expr: 0, size: 0)
)
}
std::tr1::tuple<*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value
)
)
}
std::tr1::tuple<*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value,
[5] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,*,*,std::tr1::_Nil,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value,
[5] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
[6] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,*,*,*,std::tr1::_Nil,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value,
[5] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
[6] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[7] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,*,*,*,*,std::tr1::_Nil>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value,
[5] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
[6] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[7] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[8] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value
)
)
}
std::tr1::tuple<*,*,*,*,*,*,*,*,*,*>{
preview (
#(
"(", $e._Impl._Value,
", ", $e._Impl._Tail._Value,
", ", $e._Impl._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
", ", $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
")"
)
)
children (
#(
[0] : $e._Impl._Value,
[1] : $e._Impl._Tail._Value,
[2] : $e._Impl._Tail._Tail._Value,
[3] : $e._Impl._Tail._Tail._Tail._Value,
[4] : $e._Impl._Tail._Tail._Tail._Tail._Value,
[5] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Value,
[6] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[7] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[8] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value,
[9] : $e._Impl._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Tail._Value
)
)
}
;------------------------------------------------------------------------------
; std::tr1::array from <array>
;------------------------------------------------------------------------------
std::tr1::array<*>{
preview (
; An actual array is previewed with its address.
; array<T, N> is previewed like vector<T>.
#(
"[",
$e._EEN_SIZE,
"](",
#array(expr: $e._Elems[$i], size: $e._EEN_SIZE),
")"
)
)
children (
; Just like an actual array.
#array(expr: $e._Elems[$i], size: $e._EEN_SIZE)
)
}
std::_Array_iterator<*>|std::_Array_const_iterator<*>{
preview (
#if ($e._EEN_IDL == 0) (
*$e._Ptr
) #else (
#if ($e._Idx == $e._EEN_SIZE) (
; array iterators are represented by _Ptr + _Idx,
; and they know how large their parent arrays are. Therefore, detecting
; end iterators is trivial.
"end"
) #else (
; Like vector iterators, array iterators are previewed with what they point to.
$e._Ptr[$e._Idx]
)
)
)
children (
#if ($e._EEN_IDL == 0) (
#([ptr] : $e._Ptr)
) #else (
#if ($e._Idx == $e._EEN_SIZE) (
; We make end iterators appear to have no children.
#array(expr: 0, size: 0)
) #else (
; An array iterator is conceptually a pointer, so we make it appear to store one.
#([ptr] : $e._Ptr + $e._Idx)
)
)
)
}
;------------------------------------------------------------------------------
; stdext::hash_map from <hash_map>
; stdext::hash_multimap from <hash_map>
; stdext::hash_set from <hash_set>
; stdext::hash_multiset from <hash_set>
;------------------------------------------------------------------------------
stdext::hash_map<*>|stdext::hash_multimap<*>|stdext::hash_set<*>|stdext::hash_multiset<*>{
preview (
#(
"[",
$e._List._Mysize,
"](",
#list(
head: $e._List._Myhead->_Next,
size: $e._List._Mysize,
next: _Next
) : $e._Myval,
")"
)
)
children (
#list(
head: $e._List._Myhead->_Next,
size: $e._List._Mysize,
next: _Next
) : $e._Myval
)
}
;------------------------------------------------------------------------------
; std::tr1::unordered_map from <unordered_map>
; std::tr1::unordered_multimap from <unordered_map>
; std::tr1::unordered_set from <unordered_set>
; std::tr1::unordered_multiset from <unordered_set>
;------------------------------------------------------------------------------
std::hash<*>{
preview ( "hash" )
children ( #array(expr: 0, size: 0) )
}
std::tr1::unordered_map<*>|std::tr1::unordered_multimap<*>|std::tr1::unordered_set<*>|std::tr1::unordered_multiset<*>{
preview (
#(
"[",
$e._List._Mysize,
"](",
#list(
head: $e._List._Myhead->_Next,
size: $e._List._Mysize,
next: _Next
) : $e._Myval,
")"
)
)
children (
#(
#([hash] : $e.comp._Hashobj),
#([equal] : $e.comp._Keyeqobj),
#list(
head: $e._List._Myhead->_Next,
size: $e._List._Mysize,
next: _Next
) : $e._Myval
)
)
}
;------------------------------------------------------------------------------
; std::tr1::basic_regex from <regex>
;------------------------------------------------------------------------------
std::tr1::basic_regex<*>{
preview (
#if ($e._Rep == 0) (
; Default construction creates an empty basic_regex.
"empty"
) #elif ($e._EEN_VIS == 1) (
; By default, _ENHANCED_REGEX_VISUALIZER is defined to be 1 in debug and 0 in ship.
; When it is 1, basic_regex stores the string from which it was constructed.
; When it is 0, basic_regex stores only the resulting finite state machine.
$e._Visualization
) #else (
; basic_regex contains many static const flags, which would be shown in the preview by default.
; Its actual members are _Rep and _Traits. _Rep holds the finite state machine, so we
; use it to preview basic_regex. (It does contain some human-readable information.)
*$e._Rep
)
)
children (
#if ($e._Rep == 0) (
; We make empty basic_regexes appear to have no children.
#array(expr: 0, size: 0)
) #elif ($e._EEN_VIS == 1) (
; We want to hide those static const flags.
; We also want to give _Visualization a fake name.
#(
#([str] : $e._Visualization),
#(_Rep : $e._Rep),
#(_Traits : $e._Traits)
)
) #else (
; We want to hide those static const flags.
#(
_Rep : $e._Rep,
_Traits : $e._Traits
)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::sub_match from <regex>
;------------------------------------------------------------------------------
std::tr1::sub_match<char const *>|std::tr1::sub_match<wchar_t const *>|std::tr1::sub_match<unsigned short const *>|std::tr1::sub_match<char *>|std::tr1::sub_match<wchar_t *>|std::tr1::sub_match<unsigned short *>{
preview (
; It would be nice if we could preview sub_match with its str().
; However, visualizers cannot handle strings represented by pointer pairs.
; Therefore, our preview contains more limited information.
#if ($e.matched) (
; If this sub_match participated in a match,
; we preview it with its length().
$e.second - $e.first
) #else (
; Otherwise, we preview it with its matched bool (i.e. "false").
; (Why not length() (i.e. "0")? It's meaningful to have
; matched == true and length() == 0.
"false"
)
)
children (
#(
; sub_match's three data members are public, but we list them here
; (a) to display matched before first and second, and
; (b) to gloss over the fact that sub_match derives from std::pair.
#(matched : $e.matched),
#(first : $e.first),
#(second : $e.second)
)
)
}
std::tr1::sub_match<std::_String_const_iterator<*> >|std::tr1::sub_match<std::_String_iterator<*> >{
preview (
#if ($e.matched) (
; We visualize ssub_match and wssub_match just like csub_match and wcsub_match,
; except that when determining the length(), we can't subtract iterators.
; We have to subtract their stored pointers.
$e.second._Ptr - $e.first._Ptr
) #else (
"false"
)
)
children (
#(
#(matched : $e.matched),
#(first : $e.first),
#(second : $e.second)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::match_results from <regex>
;------------------------------------------------------------------------------
std::tr1::match_results<*>{
preview (
; A match_results object is empty iff its vector _Matches is empty.
#if ($e._Matches._Myfirst == $e._Matches._Mylast) (
"empty"
) #else (
; We preview a non-empty match_results object with its vector.
$e._Matches
)
)
children (
#if ($e._Matches._Myfirst == $e._Matches._Mylast) (
; We make empty match_results appear to have no children.
#array(expr: 0, size: 0)
) #else (
; As match_results has operator[](), prefix(), and suffix() member functions,
; we make it appear to directly contain [0], [1], [2], etc. elements,
; as well as [prefix] and [suffix] elements.
#(
#array(expr: $e._Matches._Myfirst[$i], size: $e._Matches._Mylast - $e._Matches._Myfirst),
#([prefix] : $e._Prefix),
#([suffix] : $e._Suffix)
)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::regex_iterator from <regex>
;------------------------------------------------------------------------------
std::tr1::regex_iterator<*>{
preview (
#if ($e._MyRe == 0) (
; We represent end-of-sequence regex_iterators with null regex pointers.
"end"
) #else (
; Dereferenceable regex_iterators return match_results when dereferenced,
; so we'll preview them with that.
$e._MyVal
)
)
children (
#if ($e._MyRe == 0) (
; We make end-of-sequence regex_iterators appear to have no children.
#array(expr: 0, size: 0)
) #else (
; For ease of understanding, we make dereferenceable regex_iterators
; appear to have data members with the "for exposition only" names from TR1.
#(
#([begin] : $e._Begin),
#([end] : $e._End),
#([pregex] : $e._MyRe),
#([flags] : $e._Flags),
#([match] : $e._MyVal)
)
)
)
}
;------------------------------------------------------------------------------
; std::tr1::regex_token_iterator from <regex>
;------------------------------------------------------------------------------
std::tr1::regex_token_iterator<*>{
preview (
#if ($e._Res == 0) (
; We represent end-of-sequence regex_token_iterators with null result pointers.
"end"
) #else (
; Dereferenceable regex_token_iterators return *result when dereferenced,
; so we'll preview them with that.
*$e._Res
)
)
children (
#if ($e._Res == 0) (
; We make end-of-sequence regex_token_iterators appear to have no children.
#array(expr: 0, size: 0)
) #else (
; For ease of understanding, we make dereferenceable regex_token_iterators
; appear to have data members with the "for exposition only" names from TR1.
#(
#([position] : $e._Pos),
#([result] : $e._Res),
#([suffix] : $e._Suffix),
#([N] : $e._Cur),
#([subs] : $e._Subs)
)
)
)
}
;------------------------------------------------------------------------------
; std::identity, etc. from <functional>
;------------------------------------------------------------------------------
std::identity<*>{
preview ( "identity" )
children ( #array(expr: 0, size: 0) )
}
std::bit_and<*>{
preview ( "bit_and" )
children ( #array(expr: 0, size: 0) )
}
std::bit_or<*>{
preview ( "bit_or" )
children ( #array(expr: 0, size: 0) )
}
std::bit_xor<*>{
preview ( "bit_xor" )
children ( #array(expr: 0, size: 0) )
}
;------------------------------------------------------------------------------
; std::unique_ptr from <memory>
;------------------------------------------------------------------------------
std::unique_ptr<*>{
preview (
#if ($e._Myptr == 0) (
"empty"
) #else (
#(
"unique_ptr ",
*$e._Myptr
)
)
)
children (
#if ($e._Myptr == 0) (
#array(expr: 0, size: 0)
) #else (
#([ptr] : $e._Myptr)
)
)
}
;------------------------------------------------------------------------------
; std::forward_list from <forward_list>
;------------------------------------------------------------------------------
std::forward_list<*>{
preview (
#(
"(",
#list(
head: $e._Myhead,
next: _Next
) : $e._Myval,
")"
)
)
children (
#list(
head: $e._Myhead,
next: _Next
) : $e._Myval
)
}
std::_Flist_iterator<*>|std::_Flist_const_iterator<*>{
preview (
#if ($e._Ptr == 0) (
"end"
) #else (
$e._Ptr->_Myval
)
)
children (
#if ($e._Ptr == 0) (
#array(expr: 0, size: 0)
) #else (
#([ptr] : &$e._Ptr->_Myval)
)
)
}
;------------------------------------------------------------------------------
; PROPVARIANT
;------------------------------------------------------------------------------
; Visualizers for VT_VECTOR C arrays
tagCAC|tagCAUB|tagCAI|tagCAUI|tagCAL|tagCAUL|tagCAFLT|tagCADBL|tagCACY|tagCADATE|tagCABSTR|tagCABSTRBLOB|tagCABOOL|tagCASCODE|tagCAPROPVARIANT|tagCAH|tagCAUH|tagCALPSTR|tagCALPWSTR|tagCAFILETIME|tagCACLIPDATA|tagCACLSID{
preview(
#(
"[", $e.cElems , "](",
#array
(
expr : ($e.pElems)[$i],
size : $e.cElems
),
")"
)
)
children
(
#array
(
expr : ($e.pElems)[$i],
size : $e.cElems
)
)
}
; Visualizers for SAFE ARRAY
tagSAFEARRAY|SAFEARRAY{
preview(
#if ($e.fFeatures & 0x0080) ; FADF_HAVEVARTYPE
(
; Switch on the variant type field - which is stored 4 bytes
; before the beginning of the SAFEARRAY type
#switch( ((unsigned *)&($e))[-1] )
#case 0x2 ; VT_I2 | VT_ARRAY
(
#(
"safearray of I2 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((signed short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x3 ; VT_I4 | VT_ARRAY
(
#(
"safearray of I4 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((signed int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x4 ; VT_R4 | VT_ARRAY
(
#(
"safearray of R4 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((float *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x5 ; VT_R8 | VT_ARRAY
(
#(
"safearray of R8 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((double *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x6 ; VT_CY | VT_ARRAY
(
#(
"safearray of CY = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((CY *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x7 ; VT_DATE | VT_ARRAY
(
#(
"safearray of DATE = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((DATE *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x8 ; VT_BSTR | VT_ARRAY
(
#(
"safearray of BSTR = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((wchar_t **)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0xa ; VT_ERROR | VT_ARRAY
(
#(
"safearray of ERROR = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((long *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0xb ; VT_BOOL | VT_ARRAY
(
#(
"safearray of BOOL = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0xc ; VT_VARIANT | VT_ARRAY
(
#(
"safearray of VARIANT = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((tagVARIANT *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x10 ; VT_I1 | VT_ARRAY
(
#(
"safearray of I1 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((signed char *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x11 ; VT_UI1 | VT_ARRAY
(
#(
"safearray of UI1 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((unsigned char *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x12 ; VT_UI2 | VT_ARRAY
(
#(
"safearray of UI2 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((unsigned short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x13 ; VT_UI4 | VT_ARRAY
(
#(
"safearray of UI4 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((unsigned int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x14 ; VT_I8 | VT_ARRAY
(
#(
"safearray of I8 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((signed __int64 *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x15 ; VT_UI8 | VT_ARRAY
(
#(
"safearray of UI8 = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((unsigned __int64 *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x16 ; VT_INT | VT_ARRAY
(
#(
"safearray of INT = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x17 ; VT_UINT | VT_ARRAY
(
#(
"safearray of UINT = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((unsigned *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x1e ; VT_LPSTR | VT_ARRAY
(
#(
"safearray of LPSTR = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((char **)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x1f ; VT_LPWSTR | VT_ARRAY
(
#(
"safearray of LPWSTR = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((wchar_t **)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x40 ; VT_FILETIME | VT_ARRAY
(
#(
"safearray of FILETIME = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((FILETIME *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x47 ; VT_CLIPDATA | VT_ARRAY
(
#(
"safearray of CLIPDATA = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((CLIPDATA *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
#case 0x48 ; VT_CLSID | VT_ARRAY
(
#(
"safearray of CLSID = [",
; output the rank array
#array( expr: $e.rgsabound[$i].cElements, size: $e.cDims),
"](",
; output the data elements
#array(
expr: ((CLSID *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
),
")"
)
)
)
#elif ($e.fFeatures & 0x0100) ; FADF_BSTR
(
#("safearray of BSTR = ",#array(expr: $e.rgsabound[$i].cElements, size: $e.cDims) : #("[",$e,"]"), "(", #array(expr: ((wchar_t * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound ), ")")
)
#elif ($e.fFeatures & 0x0200) ; FADF_UNKNOWN
(
#("safearray of IUnknown* = [",#array(expr: $e.rgsabound[$i].cElements, size: $e.cDims), "](", #array(expr: ((IUnknown * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound ), ")")
)
#elif ($e.fFeatures & 0x0400) ; FADF_DISPATCH
(
#("safearray of IDispatch* = [",#array(expr: $e.rgsabound[$i].cElements, size: $e.cDims), "](", #array(expr: ((IDispatch * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound ), ")")
)
#elif ($e.fFeatures & 0x0800) ; FADF_VARIANT
(
#("safearray of VARIANT = ",#array(expr: $e.rgsabound[$i].cElements, size: $e.cDims) : #("[",$e,"]"), "(", #array(expr: ((tagVARIANT *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound ), ")")
)
)
children
(
#( ;[actual members]: [$e,!],
#if ($e.fFeatures & 0x0080) ; FADF_HAVEVARTYPE
(
#switch( ((unsigned *)&($e))[-1] ) ; for some reason the VT field is before the SAFEARRAY struct
#case 2 ; VT_I2|VT_ARRAY
(
#array(
expr: ((signed short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 3 ; VT_I4|VT_ARRAY
(
#array(
expr: ((signed int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 4 ; VT_R4|VT_ARRAY
(
#array(
expr: ((float *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 5 ; VT_R8|VT_ARRAY
(
#array(
expr: ((double *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x10 ; VT_I1|VT_ARRAY
(
#array(
expr: ((signed char *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x11 ; VT_UI1|VT_ARRAY
(
#array(
expr: ((unsigned char *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x12 ; VT_UI2|VT_ARRAY
(
#array(
expr: ((unsigned short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x13 ; VT_UI4|VT_ARRAY
(
#array(
expr: ((unsigned int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x14 ; VT_I8|VT_ARRAY
(
#array(
expr: ((signed __int64 *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x15 ; VT_UI8|VT_ARRAY
(
#array(
expr: ((unsigned __int64 *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x1e ; VT_LPSTR|VT_ARRAY
(
#array(
expr: ((char * *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x1f ; VT_LPWSTR|VT_ARRAY
(
#array(
expr: ((wchar_t **)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0xc ; VT_VARIANT|VT_ARRAY
(
#array(
expr: ((tagVARIANT *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0xb ; VT_BOOL|VT_ARRAY
(
#array(
expr: ((short *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0xa ; VT_ERROR|VT_ARRAY
(
#array(
expr: ((long *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 6 ; VT_CY|VT_ARRAY
(
#array(
expr: ((CY *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 7 ; VT_DATE|VT_ARRAY
(
#array(
expr: ((DATE *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x40 ; VT_FILETIME|VT_ARRAY
(
#array(
expr: ((FILETIME *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x48 ; VT_CLSID|VT_ARRAY
(
#array(
expr: ((CLSID *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x47 ; VT_CF|VT_ARRAY
(
#array(
expr: ((CLIPDATA *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 8 ; VT_BSTR|VT_ARRAY
(
#array(
expr: ((wchar_t * *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x16 ; VT_INT|VT_ARRAY
(
#array(
expr: ((int *)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#case 0x17 ; VT_UINT|VT_ARRAY
(
#array(
expr: ((unsigned int*)$e.pvData)[$i],
size: $e.rgsabound[$r].cElements,
rank: $e.cDims,
base: $e.rgsabound[$r].lLbound
)
)
#default
(
#([actual members]: [$e,!])
)
#except
(
#([actual members]: [$e,!])
)
)
#elif ($e.fFeatures & 0x0100) ; FADF_BSTR
(
#array(expr: ((wchar_t * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound )
)
#elif ($e.fFeatures & 0x0200) ; FADF_UNKNOWN
(
#array(expr: ((IUnknown * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound )
)
#elif ($e.fFeatures & 0x0400) ; FADF_DISPATCH
(
#array(expr: ((IDispatch * *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound )
)
#elif ($e.fFeatures & 0x0800) ; FADF_VARIANT
(
#array(expr: ((tagVARIANT *)$e.pvData)[$i], size: $e.rgsabound[$r].cElements, rank: $e.cDims, base: $e.rgsabound[$r].lLbound )
)
)
)
}
tagPROPVARIANT|tagVARIANT|PROPVARIANT|VARIANT{
preview(
#switch ($e.vt)
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Base Types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0 ( #("Empty") ) ; VT_EMPTY
#case 1 ( #("NULL") ) ; VT_NULL
#case 2 ( #("I2 = ", $e.iVal) ) ; VT_I2
#case 3 ( #("I4 = ", $e.lVal) ) ; VT_I4
#case 4 ( #("R4 = ", $e.fltVal) ) ; VT_R4
#case 5 ( #("R8 = ", $e.dblVal) ) ; VT_R8
#case 6 ( #("CY = ", $e.cyVal) ) ; VT_CY
#case 7 ( #("DATE = ", $e.date) ) ; VT_DATE
#case 8 ( #("BSTR = ", $e.bstrVal) ) ; VT_BSTR
#case 9 ( #("DISPATCH = ", $e.pdispVal) ) ; VT_DISPATCH
#case 10 ( #("ERROR = ", $e.scode) ) ; VT_ERROR
#case 0xB ( #("BOOL = ", $e.boolVal) ) ; VT_BOOL
#case 0xC ( #("VARIANT ") ) ; VT_VARIANT
#case 0xD ( #("UNKNOWN = ", $e.punkVal) ) ; VT_UNKOWN
#case 0xE ( #("DECIMAL = ", $e.decVal) ) ; VT_DECIMAL
#case 0x10 ( #("I1 = ", $e.cVal) ) ; VT_I1
#case 0x11 ( #("UI1 = ", $e.bVal) ) ; VT_UI1
#case 0x12 ( #("UI2 = ", $e.uiVal) ) ; VT_UI2
#case 0x13 ( #("UI4 = ", $e.ulVal) ) ; VT_UI4
#case 0x14 ( #("I8 = ", *(__int64*)&$e.dblVal) ) ; VT_I8
#case 0x15 ( #("UI8 = ", *(unsigned __int64*)&$e.dblVal) ) ; VT_UI8
#case 0x16 ( #("INT = ", $e.intVal) ) ; VT_INT
#case 0x17 ( #("UINT = ", $e.uintVal) ) ; VT_UINT
#case 0x18 ( #("VOID ") ) ; VT_VOID
#case 0x19 ( #("HRESULT ") ) ; VT_HRESULT
#case 0x1A ( #("PTR ") ) ; VT_PTR
#case 0x1B ( #("SAFEARRAY ") ) ; VT_SAFEARRAY
#case 0x1C ( #("CARRAY ") ) ; VT_CARRAY
#case 0x1D ( #("USERDEFINED ") ) ; VT_USERDEFINED
#case 0x1E ( #("LPSTR = ", $e.pszVal) ) ; VT_LPSTR
#case 0x1F ( #("LPWSTR = ", $e.pwszVal) ) ; VT_LPWSTR
#case 0x24 ( #("RECORD ") ) ; VT_RECORD
#case 0x26 ( #("UINT_PTR ") ) ; VT_UINT_PTR
#case 0x40 ( #("FILETIME = ", $e.filetime) ) ; VT_FILETIME
#case 0x42 ( #("STREAM = ", $e.pStream) ) ; VT_STREAM
#case 0x43 ( #("STORAGE = ", $e.pStorage) ) ; VT_STORAGE
#case 0x44 ( #("STREAMED_OBJECT = ", $e.pStream) ) ; VT_STREAMED_OBJECT
#case 0x45 ( #("STORED_OBJECT = ", $e.pStorage) ) ; VT_STORED_OBJECT
#case 0x46 ( #("BLOB_OBJECT = ", $e.blob ) ) ; VT_BLOB_OBJECT
#case 0x47 ( #("CF = ", $e.pclipdata) ) ; VT_CF
#case 0x48 ( #("CLSID = ", $e.puuid) ) ; VT_CLSID
#case 0x49 ( #("VERSIONED_STREAM = ", $e.pVersionedStream) ) ; VT_VERSIONED_STREAM
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Vector types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0x1002 ( #("vector of I2 = ", $e.cai) ) ; VT_I2|VT_VECTOR
#case 0x1003 ( #("vector of I4 = ", $e.cal) ) ; VT_I4|VT_VECTOR
#case 0x1004 ( #("vector of R4 = ", $e.caflt) ) ; VT_R4|VT_VECTOR
#case 0x1005 ( #("vector of R8 = ", $e.cadbl) ) ; VT_R8|VT_VECTOR
#case 0x1010 ( #("vector of I1 = ", $e.cac) ) ; VT_I1|VT_VECTOR
#case 0x1011 ( #("vector of UI1 = ", $e.caub) ) ; VT_UI1|VT_VECTOR
#case 0x1012 ( #("vector of UI2 = ", $e.caui) ) ; VT_UI2|VT_VECTOR
#case 0x1013 ( #("vector of UI4 = ", $e.caul) ) ; VT_UI4|VT_VECTOR
#case 0x1014 ( #("vector of I8 = ", $e.cah) ) ; VT_I8|VT_VECTOR
#case 0x1015 ( #("vector of UI8 = ", $e.cauh) ) ; VT_UI8|VT_VECTOR
#case 0x101E ( #("vector of LPSTR = ", $e.calpstr) ) ; VT_LPSTR|VT_VECTOR
#case 0x101F ( #("vector of LPWSTR = ", $e.calpwstr) ) ; VT_LPWSTR|VT_VECTOR
#case 0x100C ( #("vector of VARIANT ", $e.capropvar) ) ; VT_VARIANT|VT_VECTOR
#case 0x100B ( #("vector of BOOL = ", $e.cabool) ) ; VT_BOOL|VT_VECTOR
#case 0x100A ( #("vector of ERROR = ", $e.cascode) ) ; VT_ERROR|VT_VECTOR
#case 0x1006 ( #("vector of CY = ", $e.cacy) ) ; VT_CY|VT_VECTOR
#case 0x1007 ( #("vector of DATE = ", $e.cadate) ) ; VT_DATE|VT_VECTOR
#case 0x1040 ( #("vector of FILETIME = ", $e.cafiletime) ) ; VT_FILETIME|VT_VECTOR
#case 0x1048 ( #("vector of CLSID = ", $e.cauuid) ) ; VT_CLSID|VT_VECTOR
#case 0x1047 ( #("vector of CF = ", $e.caclipdata) ) ; VT_CF|VT_VECTOR
#case 0x1008 ( #("vector of BSTR = ", $e.cabstr) ) ; VT_BSTR|VT_VECTOR
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Byref Types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0x4016 ( #("byref of INT = ", $e.pintVal) ) ; VT_INT|VT_BYREF
#case 0x4017 ( #("byref of UINT = ", $e.puintVal) ) ; VT_UINT|VT_BYREF
#case 0x4002 ( #("byref of I2 = ", $e.piVal) ) ; VT_I2|VT_BYREF
#case 0x4003 ( #("byref of I4 = ", $e.plVal) ) ; VT_I4|VT_BYREF
#case 0x4004 ( #("byref of R4 = ", $e.pfltVal) ) ; VT_R4|VT_BYREF
#case 0x4005 ( #("byref of R8 = ", $e.pdblVal) ) ; VT_R8|VT_BYREF
#case 0x4010 ( #("byref of I1 = ", $e.pcVal) ) ; VT_I1|VT_BYREF
#case 0x4011 ( #("byref of UI1 = ", $e.pbVal) ) ; VT_UI1|VT_BYREF
#case 0x4012 ( #("byref of UI2 = ", $e.puiVal) ) ; VT_UI2|VT_BYREF
#case 0x4013 ( #("byref of UI4 = ", $e.pulVal) ) ; VT_UI4|VT_BYREF
#case 0x4014 ( #("byref of I8 = ", (__int64*)$e.pdblVal) ) ; VT_I8|VT_BYREF
#case 0x4015 ( #("byref of UI8 = ", (unsigned __int64*)$e.pudblVal) ) ; VT_UI8|VT_BYREF
#case 0x400C ( #("byref of VARIANT ", $e.pvarVal) ) ; VT_VARIANT|VT_BYREF
#case 0x400B ( #("byref of BOOL = ", $e.pboolVal) ) ; VT_BOOL|VT_BYREF
#case 0x400A ( #("byref of ERROR = ", $e.pscode) ) ; VT_ERROR|VT_BYREF
#case 0x4006 ( #("byref of CY = ", $e.pcyVal) ) ; VT_CY|VT_BYREF
#case 0x4007 ( #("byref of DATE = ", $e.pdate) ) ; VT_DATE|VT_BYREF
#case 0x4008 ( #("byref of BSTR = ", $e.pbstrVal) ) ; VT_BSTR|VT_BYREF
#case 0x400E ( #("byref of DECIMAL = ", $e.pdecVal) ) ; VT_DECIMAL|VT_BYREF
#case 0x400D ( #("byref of UNKNOWN = ", $e.ppunkVal) ) ; VT_UNKOWN|VT_BYREF
#case 0x4009 ( #("byref of DISPATCH = ", $e.ppdispVal) ) ; VT_DISPATCH|VT_BYREF
#case 0x6000 ( #("byref of ARRAY = ", $e.pparray) ) ; VT_ARRAY|VT_BYREF
#default
(
#if ($e.vt & 0x2000) ( $e.parray)
#else ( #("Unknown vt type = ", $e.vt))
)
)
children(
#(
vt: $e.vt,
#switch ($e.vt)
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Base Types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0x2 ( #(I2 : $e.iVal) ) ; VT_I2
#case 0x3 ( #(I4 : $e.lVal) ) ; VT_I4
#case 0x4 ( #(R4 : $e.fltVal) ) ; VT_R4
#case 0x5 ( #(R8 : $e.dblVal) ) ; VT_R8
#case 0x6 ( #(CY : $e.cyVal) ) ; VT_CY
#case 0x7 ( #(DATE : $e.date) ) ; VT_DATE
#case 0x8 ( #(BSTR : $e.bstrVal) ) ; VT_BSTR
#case 0x9 ( #(DISPATCH : $e.pdispVal) ) ; VT_DISPATCH
#case 0xA ( #(ERROR : $e.scode) ) ; VT_ERROR
#case 0xB ( #(BOOL : $e.boolVal) ) ; VT_BOOL
#case 0xD ( #(UNKNOWN : $e.punkVal) ) ; VT_UNKOWN
#case 0xE ( #(DECIMAL : $e.decVal) ) ; VT_DECIMAL
#case 0x10 ( #(I1 : $e.cVal) ) ; VT_I1
#case 0x11 ( #(UI1 : $e.bVal) ) ; VT_UI1
#case 0x12 ( #(UI2 : $e.uiVal) ) ; VT_UI2
#case 0x13 ( #(UI4 : $e.ulVal) ) ; VT_UI4
#case 0x14 ( #(I8 : *(__int64*)&$e.dblVal) ) ; VT_I8
#case 0x15 ( #(UI8 : *(unsigned __int64*)&$e.dblVal) ) ; VT_UI8
#case 0x16 ( #(INT : $e.intVal) ) ; VT_INT
#case 0x17 ( #(UINT : $e.uintVal) ) ; VT_UINT
#case 0x1E ( #(LPSTR : $e.pszVal) ) ; VT_LPSTR
#case 0x1F ( #(LPWSTR : $e.pwszVal) ) ; VT_LPWSTR
#case 0x40 ( #(FILETIME : $e.filetime) ) ; VT_FILETIME
#case 0x42 ( #(STREAM : $e.pStream) ) ; VT_STREAM
#case 0x43 ( #(STORAGE : $e.pStorage) ) ; VT_STORAGE
#case 0x44 ( #(STREAMED_OBJECT : $e.pStream) ) ; VT_STREAMED_OBJECT
#case 0x45 ( #(STORED_OBJECT : $e.pStorage) ) ; VT_STORED_OBJECT
#case 0x46 ( #(BLOB_OBJECT : $e.blob ) ) ; VT_BLOB_OBJECT
#case 0x47 ( #(CF : $e.pclipdata) ) ; VT_CF
#case 0x48 ( #(CLSID : $e.puuid) ) ; VT_CLSID
#case 0x49 ( #(VERSIONED_STREAM : $e.pVersionedStream) ) ; VT_VERSIONED_STREAM
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Vector types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0x1002 ( #(vector of I2 : $e.cai) ) ; VT_I2|VT_VECTOR
#case 0x1003 ( #(vector of I4 : $e.cal) ) ; VT_I4|VT_VECTOR
#case 0x1004 ( #(vector of R4 : $e.caflt) ) ; VT_R4|VT_VECTOR
#case 0x1005 ( #(vector of R8 : $e.cadbl) ) ; VT_R8|VT_VECTOR
#case 0x1010 ( #(vector of I1 : $e.cac) ) ; VT_I1|VT_VECTOR
#case 0x1011 ( #(vector of UI1 : $e.caub) ) ; VT_UI1|VT_VECTOR
#case 0x1012 ( #(vector of UI2 : $e.caui) ) ; VT_UI2|VT_VECTOR
#case 0x1013 ( #(vector of UI4 : $e.caul) ) ; VT_UI4|VT_VECTOR
#case 0x1014 ( #(vector of I8 : $e.cah) ) ; VT_I8|VT_VECTOR
#case 0x1015 ( #(vector of UI8 : $e.cauh) ) ; VT_UI8|VT_VECTOR
#case 0x101E ( #(vector of LPSTR : $e.calpstr) ) ; VT_LPSTR|VT_VECTOR
#case 0x101F ( #(vector of LPWSTR : $e.calpwstr) ) ; VT_LPWSTR|VT_VECTOR
#case 0x100C ( #(vector of VARIANT : $e.capropvar) ) ; VT_VARIANT|VT_VECTOR
#case 0x100B ( #(vector of BOOL : $e.cabool) ) ; VT_BOOL|VT_VECTOR
#case 0x100A ( #(vector of ERROR : $e.cascode) ) ; VT_ERROR|VT_VECTOR
#case 0x1006 ( #(vector of CY : $e.cacy) ) ; VT_CY|VT_VECTOR
#case 0x1007 ( #(vector of DATE : $e.cadate) ) ; VT_DATE|VT_VECTOR
#case 0x1040 ( #(vector of FILETIME : $e.cafiletime) ) ; VT_FILETIME|VT_VECTOR
#case 0x1048 ( #(vector of CLSID : $e.cauuid) ) ; VT_CLSID|VT_VECTOR
#case 0x1047 ( #(vector of CF : $e.caclipdata) ) ; VT_CF|VT_VECTOR
#case 0x1008 ( #(vector of BSTR : $e.cabstr) ) ; VT_BSTR|VT_VECTOR
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Byref Types ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
#case 0x4016 ( #(byref of INT : $e.pintVal) ) ; VT_INT|VT_BYREF
#case 0x4017 ( #(byref of UINT : $e.puintVal) ) ; VT_UINT|VT_BYREF
#case 0x4002 ( #(byref of I2 : $e.piVal) ) ; VT_I2|VT_BYREF
#case 0x4003 ( #(byref of I4 : $e.plVal) ) ; VT_I4|VT_BYREF
#case 0x4004 ( #(byref of R4 : $e.pfltVal) ) ; VT_R4|VT_BYREF
#case 0x4005 ( #(byref of R8 : $e.pdblVal) ) ; VT_R8|VT_BYREF
#case 0x4010 ( #(byref of I1 : $e.pcVal) ) ; VT_I1|VT_BYREF
#case 0x4011 ( #(byref of UI1 : $e.pbVal) ) ; VT_UI1|VT_BYREF
#case 0x4012 ( #(byref of UI2 : $e.puiVal) ) ; VT_UI2|VT_BYREF
#case 0x4013 ( #(byref of UI4 : $e.pulVal) ) ; VT_UI4|VT_BYREF
#case 0x4014 ( #(byref of I8 : (__int64*)$e.pdblVal) ) ; VT_I8|VT_BYREF
#case 0x4015 ( #(byref of UI8 : (unsigned __int64*)$e.pdblVal) ) ; VT_UI8|VT_BYREF
#case 0x400C ( #(byref of VARIANT : $e.pvarVal) ) ; VT_VARIANT|VT_BYREF
#case 0x400B ( #(byref of BOOL : $e.pboolVal) ) ; VT_BOOL|VT_BYREF
#case 0x400A ( #(byref of ERROR : $e.pscode) ) ; VT_ERROR|VT_BYREF
#case 0x4006 ( #(byref of CY : $e.pcyVal) ) ; VT_CY|VT_BYREF
#case 0x4007 ( #(byref of DATE : $e.pdate) ) ; VT_DATE|VT_BYREF
#case 0x4008 ( #(byref of BSTR : $e.pbstrVal) ) ; VT_BSTR|VT_BYREF
#case 0x400E ( #(byref of DECIMAL : $e.pdecVal) ) ; VT_DECIMAL|VT_BYREF
#case 0x400D ( #(byref of UNKNOWN : $e.ppunkVal) ) ; VT_UNKOWN|VT_BYREF
#case 0x4009 ( #(byref of DISPATCH : $e.ppdispVal) ) ; VT_DISPATCH|VT_BYREF
#case 0x6000 ( #(byref of ARRAY : $e.pparray) ) ; VT_ARRAY|VT_BYREF
; the following are either empty or invalid vt values for a variant
; #case 0 ( #(Empty :) ) ; VT_EMPTY
; #case 0x1 ( #(NULL :) ) ; VT_NULL
; #case 0xC ( #(VARIANT :) ) ; VT_VARIANT
; #case 0x18 ( #(VOID :) ) ; VT_VOID
; #case 0x19 ( #(HRESULT :) ) ; VT_HRESULT
; #case 0x1A ( #(PTR :) ) ; VT_PTR
; #case 0x1B ( #(SAFEARRAY :) ) ; VT_SAFEARRAY
; #case 0x1C ( #(CARRAY :) ) ; VT_CARRAY
; #case 0x1D ( #(USERDEFINED :) ) ; VT_USERDEFINED
; #case 0x24 ( #(RECORD :) ) ; VT_RECORD
; #case 0x26 ( #(UINT_PTR :) ) ; VT_UINT_PTR
#default
(
#if ($e.vt & 0x2000 )
( #(safearray: $e.parray))
#else
(
#(
[raw members]: [$e,!] ; unformatted data members
)
)
)
#except
(
#(
[raw members]: [$e,!] ; unformatted data members
)
)
)
)
}
; Visualizers for data structures in namespace Concurrency
;------------------------------------------------------------------------------
; Concurrency::message from <agents.h>
;------------------------------------------------------------------------------
Concurrency::message<*>{
preview (
#(
$e.payload
)
)
children (
#(
#(payload: $e.payload),
#([msg_id]: $e._M_id)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::multi_link_registry from <agents.h>
;------------------------------------------------------------------------------
Concurrency::multi_link_registry<*>{
preview (
#(
"[",
$e._M_vector._M_index,
"](",
#array(
expr: *($e._M_vector._M_array[$i]),
size: $e._M_vector._M_index
),
")"
)
)
children (
#(
#([size]: $e._M_vector._M_index),
#array(
expr: *($e._M_vector._M_array[$i]),
size: $e._M_vector._M_index
)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::_Queue from <agents.h>
;------------------------------------------------------------------------------
Concurrency::details::_Queue<*>{
preview (
#(
"[",
$e._M_count,
"](",
#list(
head: $e._M_pHead,
next: _M_pNext,
size: _M_count
),
")"
)
)
children (
#(
#([size]: $e._M_count),
#list(
head: $e._M_pHead,
next: _M_pNext,
size: _M_count
)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::unbounded_buffer from <agents.h>
;------------------------------------------------------------------------------
Concurrency::unbounded_buffer<*>{
preview (
#(
$e._M_messageBuffer
)
)
children (
#(
#(unprocessed_messages: $e._M_messageProcessor._M_queuedMessages._M_queue),
#(messages: $e._M_messageBuffer),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(linked_targets: $e._M_connectedTargets),
#(reserving_target: *($e._M_pReservedFor)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::overwrite_buffer from <agents.h>
;------------------------------------------------------------------------------
Concurrency::overwrite_buffer<*>{
preview (
#(
$e._M_pMessage
)
)
children (
#(
#(value: *($e._M_pMessage)),
#(unprocessed_messages: $e._M_messageProcessor._M_queuedMessages._M_queue),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(linked_targets: $e._M_connectedTargets),
#(reserving_target: *($e._M_pReservedFor)),
#(reserved_message: *($e._M_pReservedMessage)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::single_assignment from <agents.h>
;------------------------------------------------------------------------------
Concurrency::single_assignment<*>{
preview (
#(
$e._M_pMessage
)
)
children (
#(
#(value: *($e._M_pMessage)),
#(unprocessed_messages: $e._M_messageProcessor._M_queuedMessages._M_queue),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(linked_targets: $e._M_connectedTargets),
#(reserving_target: *($e._M_pReservedFor)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::call from <agents.h>
;------------------------------------------------------------------------------
Concurrency::call<*>{
preview (
#(
$e._M_pFunc
)
)
children (
#(
#(call_method: $e._M_pFunc),
#(unprocessed_messages: $e._M_messageProcessor._M_queuedMessages._M_queue),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::transformer from <agents.h>
;------------------------------------------------------------------------------
Concurrency::transformer<*>{
preview (
#(
$e._M_pFunc
)
)
children (
#(
#(transform_method: $e._M_pFunc),
#(unprocessed_messages: $e._M_messageProcessor._M_queuedMessages._M_queue),
#(messages: $e._M_messageBuffer),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(linked_target: *($e._M_connectedTargets._M_connectedLink)),
#(reserving_target: *($e._M_pReservedFor)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::choice from <agents.h>
;------------------------------------------------------------------------------
Concurrency::choice<*>{
preview (
#(
"[",
#if ($e._M_pSingleAssignment->_M_fIsInitialized) ("initialized")
#else ("not_initialized"),
"] ",
$e._M_sourceTuple
)
)
children (
#(
#([input_count]: $e._M_pSingleAssignment->_M_connectedSources._M_links._M_vector._M_index),
#(index: $e._M_pSingleAssignment->_M_pMessage->payload),
#(source_tuple: $e._M_sourceTuple),
#(linked_sources: $e._M_pSingleAssignment->_M_connectedSources._M_links),
#(linked_targets: $e._M_pSingleAssignment->_M_connectedTargets),
#(reserving_target: *($e._M_pSingleAssignment->_M_pReservedFor)),
#(Scheduler: *($e._M_pScheduler)),
#(ScheduleGroup: *($e._M_pScheduleGroup)),
#([raw _M_pSourceChoices] : $e._M_pSourceChoices)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::join<*,*>::_MessageArray from <agents.h>
;------------------------------------------------------------------------------
Concurrency::join<*,*>::_MessageArray{
preview (
#(
"[",
$e._M_count,
"](",
#array(
expr: *(((Concurrency::message<$T1>**)$e._M_messages)[$i]),
size: $e._M_count
),
")"
)
)
children (
#(
#([size]: $e._M_count),
#array(
expr: *(((Concurrency::message<$T1>**)$e._M_messages)[$i]),
size: $e._M_count
)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::join<*,*>::_SavedMessageIdArray from <agents.h>
;------------------------------------------------------------------------------
Concurrency::join<*,*>::_SavedMessageIdArray{
preview (
#(
"[",
$e._M_count,
"](",
#array(
expr: ((int*)$e._M_savedIds)[$i],
size: $e._M_count
),
")"
)
)
children (
#(
#([size]: $e._M_count),
#array(
expr: ((int*)$e._M_savedIds)[$i],
size: $e._M_count
)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::join from <agents.h>
;------------------------------------------------------------------------------
Concurrency::join<*,*>{
preview (
#(
"[",
$e._M_messageArray._M_count - $e._M_messagesRemaining,
"/",
$e._M_messageArray._M_count,
"](",
#array(
expr: *($e._M_connectedSources._M_links._M_vector._M_array[$i]),
size: $e._M_connectedSources._M_links._M_vector._M_index
),
")"
)
)
children (
#(
#([join_type]: (Concurrency::join_type)$T2),
#([offer_count]: $e._M_messageArray._M_count - $e._M_messagesRemaining),
#(offer_IDs: $e._M_savedMessageIdArray),
#([input_count]: $e._M_messageArray._M_count),
#(input_values: $e._M_messageArray),
#(messages: $e._M_messageBuffer),
#(message_filter: *($e._M_pFilter)),
#(linked_sources: $e._M_connectedSources._M_links),
#(linked_target: $e._M_connectedTargets._M_connectedLink),
#(reserving_target: *($e._M_pReservedFor)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::multitype_join from <agents.h>
;------------------------------------------------------------------------------
Concurrency::multitype_join<*,*>{
preview (
#(
"[",
$e._M_pJoinNode->_M_connectedSources._M_links._M_vector._M_index - $e._M_pJoinNode->_M_counter,
"/",
$e._M_pJoinNode->_M_connectedSources._M_links._M_vector._M_index,
"]",
$e._M_sourceTuple
)
)
children (
#(
#([join_type]: (Concurrency::join_type)$T2),
#([offer_count]: $e._M_pJoinNode->_M_connectedSources._M_links._M_vector._M_index - $e._M_pJoinNode->_M_counter),
#([input_count]: $e._M_pJoinNode->_M_connectedSources._M_links._M_vector._M_index),
#(source_tuple: $e._M_sourceTuple),
#(messages: $e._M_pJoinNode->_M_messageBuffer),
#(linked_sources: $e._M_pJoinNode->_M_connectedSources._M_links),
#(linked_target: $e._M_pJoinNode->_M_connectedTargets._M_connectedLink),
#(reserving_target: *($e._M_pJoinNode->_M_pReservedFor)),
#(Scheduler: *($e._M_pJoinNode->_M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_pJoinNode->_M_messageProcessor._M_pScheduleGroup)),
#([raw _M_pSourceJoins] : $e._M_pSourceJoins)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::timer from <agents.h>
;------------------------------------------------------------------------------
Concurrency::timer<*>{
preview (
#(
$e._M_state
)
)
children (
#(
#(state: $e._M_state),
#(value: $e._M_value),
#(repeating: $e._M_fRepeating),
#(interval_ms: $e._M_ms),
#(linked_target: *($e._M_connectedTargets._M_connectedLink)),
#(reserving_target: *($e._M_pReservedFor)),
#(Scheduler: *($e._M_messageProcessor._M_pScheduler)),
#(ScheduleGroup: *($e._M_messageProcessor._M_pScheduleGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::SchedulerBase from <SchedulerBase.h>
; Concurrency::details::ThreadScheduler from <ThreadScheduler.h>
; Concurrency::details::UMSThreadScheduler from <UMSThreadScheduler.h>
;------------------------------------------------------------------------------
Concurrency::details::SchedulerBase|Concurrency::details::ThreadScheduler|Concurrency::details::UMSThreadScheduler{
preview (
#(
"[",
$e.m_id,
"] ",
#if ($e.m_schedulerKind == 0) ("ThreadScheduler")
#else ("UmsScheduler"),
#if ($e.m_id == $e.s_pDefaultScheduler->m_id) (", default")
#else ("")
)
)
children (
#(
#(ID: $e.m_id),
#(SchedulerPolicy: $e.m_policy),
#(VirtualProcessorCount: $e.m_virtualProcessorCount),
#(ReferenceCount: $e.m_refCount),
#([isDefaultScheduler]: $e.m_id == $e.s_pDefaultScheduler->m_id)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::ScheduleGroupBase from <ScheduleGroupBase.h>
; Concurrency::details::CacheLocalScheduleGroup from <CacheLocalScheduleGroup.h>
; Concurrency::details::FairScheduleGroup from <FairScheduleGroup.h>
;------------------------------------------------------------------------------
Concurrency::details::ScheduleGroupBase|Concurrency::details::CacheLocalScheduleGroup|Concurrency::details::FairScheduleGroup{
preview (
#(
"[",
$e.m_id,
"]",
#if ($e.m_kind & 4) (" AnonymousScheduleGroup")
#else ("")
)
)
children (
#(
#(ID: $e.m_id),
#(Scheduler: *($e.m_pScheduler))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::ContextBase from <ContextBase.h>
; Concurrency::details::InternalContextBase from <InternalContextBase.h>
; Concurrency::details::ThreadInternalContext from <ThreadInternalContext.h>
; Concurrency::details::UMSThreadInternalContext from <UMSThreadInternalContext.h>
;------------------------------------------------------------------------------
Concurrency::details::ContextBase|Concurrency::details::InternalContextBase|Concurrency::details::ThreadInternalContext|Concurrency::details::UMSThreadInternalContext{
preview (
#(
"[",
$e.m_threadId,
"] ",
#if ($e.m_blockedState == 0) ("not_concrt_blocked")
#elif ($e.m_blockedState == 1) ("concrt_blocked")
#elif ($e.m_blockedState == 2) ("ums_sync_blocked")
#elif ($e.m_blockedState == 4) ("ums_async_blocked")
#else ("")
)
)
children (
#(
#(ID: $e.m_id),
#(ThreadID: $e.m_threadId),
#(Scheduler: *($e.m_pScheduler)),
#(ScheduleGroup: *($e.m_pGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::ExternalContextBase from <ExternalContextBase.h>
;------------------------------------------------------------------------------
Concurrency::details::ExternalContextBase{
preview (
#(
"[",
$e.m_threadId,
"] ",
#if ($e.m_contextSwitchingFence == 1) ("concrt_blocked")
#else ("not_concrt_blocked")
)
)
children (
#(
#(ID: $e.m_id),
#(ThreadID: $e.m_threadId),
#(Scheduler: *($e.m_pScheduler)),
#(ScheduleGroup: *($e.m_pGroup))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::SchedulerPolicy from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::SchedulerPolicy{
preview (
#(
$e._M_pPolicyBag->_M_values._M_specificValues._M_schedulerKind,
", Min=",
$e._M_pPolicyBag->_M_values._M_specificValues._M_minConcurrency,
", Max=",
$e._M_pPolicyBag->_M_values._M_specificValues._M_maxConcurrency
)
)
children (
#(
#(SchedulerKind: $e._M_pPolicyBag->_M_values._M_specificValues._M_schedulerKind),
#(MinConcurrency: $e._M_pPolicyBag->_M_values._M_specificValues._M_minConcurrency),
#(MaxConcurrency: $e._M_pPolicyBag->_M_values._M_specificValues._M_maxConcurrency),
#(TargetOversubscriptionFactor: $e._M_pPolicyBag->_M_values._M_specificValues._M_targetOversubscriptionFactor),
#(LocalContextCacheSize: $e._M_pPolicyBag->_M_values._M_specificValues._M_localContextCacheSize),
#(ContextStackSize: $e._M_pPolicyBag->_M_values._M_specificValues._M_contextStackSize),
#(ContextPriority: $e._M_pPolicyBag->_M_values._M_specificValues._M_contextPriority),
#(SchedulingProtocol: $e._M_pPolicyBag->_M_values._M_specificValues._M_schedulingProtocol),
#(DynamicProgressFeedback: $e._M_pPolicyBag->_M_values._M_specificValues._M_dynamicProgressFeedback)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::event from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::event{
preview (
#(
#if ($e._M_pWaitChain == 1) ("set")
#else ("not_set")
)
)
children (
#(
#([is_set]: ($e._M_pWaitChain == 1)),
#([has_waiters]: (($e._M_pWaitChain != 0) && ($e._M_pWaitChain != 1)))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::critical_section from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::critical_section{
preview (
#(
#if ($e._M_pHead != 0) ("locked")
#else ("not_locked")
)
)
children (
#(
#([is_locked]: ($e._M_pHead != 0)),
#(OwningContext: *((Concurrency::Context*)($e._M_activeNode[0])))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::critical_section::scoped_lock from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::critical_section::scoped_lock{
preview (
#(
$e._M_critical_section
)
)
children (
#(
CriticalSection: $e._M_critical_section
)
)
}
;------------------------------------------------------------------------------
; Concurrency::reader_writer_lock from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::reader_writer_lock{
preview (
#(
#if (($e._M_lockState < 8) && ($e._M_lockState & 2)) ("held_by_writer")
#elif ($e._M_lockState >= 8) (
#(
"held_by_reader(s) [",
($e._M_lockState / 8),
"]"
)
)
#else ("not_held")
)
)
children (
#(
#([is_reader_lock_held]: ($e._M_lockState >= 8)),
#([num_reader_lock_holders]: ($e._M_lockState / 8)),
#([is_writer_lock_held]: ($e._M_lockState < 8) && ($e._M_lockState & 2)),
#(OwningWriterContext: *((Concurrency::Context*)($e._M_activeWriter[0])))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::reader_writer_lock::scoped_lock from <concrt.h>
; Concurrency::reader_writer_lock::scoped_lock_read from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::reader_writer_lock::scoped_lock|Concurrency::reader_writer_lock::scoped_lock_read{
preview (
#(
$e._M_reader_writer_lock
)
)
children (
#(
ReaderWriterLock: $e._M_reader_writer_lock
)
)
}
;------------------------------------------------------------------------------
; Concurrency::details::_TaskCollectionBase from <concrt.h>
;------------------------------------------------------------------------------
Concurrency::details::_TaskCollectionBase{
preview (
#(
#if ((((int)$e._M_pException & ~0x3) != 0) && (((int)$e._M_pException & ~0x3) != 0xC)) ("exception")
#else ("no_exception")
)
)
children (
#(
#([has_exception]: (((int)$e._M_pException & ~0x3) != 0) && (((int)$e._M_pException & ~0x3) != 0xC)),
#(CreatingContext: *((Concurrency::Context*)$e._M_pOwningContext))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::task_group from <ppl.h>
; Concurrency::structured_task_group from <ppl.h>
;------------------------------------------------------------------------------
Concurrency::task_group|Concurrency::structured_task_group{
preview (
#(
#if ((((int)$e._M_task_collection._M_pException & ~0x3) != 0) && (((int)$e._M_task_collection._M_pException & ~0x3) != 0xC)) ("exception")
#else ("no_exception")
)
)
children (
#(
#([has_exception]: (((int)$e._M_task_collection._M_pException & ~0x3) != 0) && (((int)$e._M_task_collection._M_pException & ~0x3) != 0xC)),
#(CreatingContext: *((Concurrency::Context*)$e._M_task_collection._M_pOwningContext))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::task_handle from <ppl.h>
;------------------------------------------------------------------------------
Concurrency::task_handle<*>{
preview (
#(
$e._M_function
)
)
children (
#(
#(Function: $e._M_function),
#(RuntimeOwnsLifetime: $e._M_fRuntimeOwnsLifetime),
#(TaskCollection: *($e._M_pTaskCollection))
)
)
}
;------------------------------------------------------------------------------
; Concurrency::combinable from <ppl.h>
;------------------------------------------------------------------------------
Concurrency::combinable<*>{
preview(
#(
"(",
#array(
expr: *($e._M_buckets[$i]),
size: $e._M_size
) : #list(
head: $e,
next: _M_chain
) : $e._M_value,
")"
)
)
children(
#(
#array(
expr: *($e._M_buckets[$i]),
size: $e._M_size
) : #list(
head: $e,
next: _M_chain
) : $e._M_value,
#(InitFunction : $e._M_fnInitialize)
)
)
}
;------------------------------------------------------------------------------
; Concurrency::concurrent_vector from <concurrent_vector.h>
;------------------------------------------------------------------------------
Concurrency::concurrent_vector<*,*>{
preview(
#(
"[",
$e._My_early_size._M_value,
"](",
#array (
expr: #(
#if (($i >> 1) == 0) ((($T1*)$e._My_segment._M_value[0]._My_array)[$i])
#else ((($T1*)$e._My_segment._M_value[__log2($i)]._My_array)[$i - (0x1 << __log2($i))])
),