Source code of Windows XP (NT5)
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

1298 lines
23 KiB

/*
* This module contains the definitions for the inline functions used by the
* name undecorator. It is intended that this file should be included
* somewhere in the source file for the undecorator to maximise the chance
* that they will be truly inlined.
*/
// The following class is a special node class, used in the implementation
// of the internal chaining mechanism of the 'DName's
class charNode;
class pcharNode;
class pDNameNode;
class DNameStatusNode;
#if ( NO_VIRTUAL )
enum NodeType
{
charNode_t,
pcharNode_t,
pDNameNode_t,
DNameStatusNode_t
};
#endif // NO_VIRTUAL
class DNameNode
{
private:
#if NO_VIRTUAL
NodeType typeIndex;
#endif // NO_VIRTUAL
DNameNode * next;
protected:
#if ( !NO_VIRTUAL )
__near DNameNode ();
#else // } elif NO_VIRTUAL {
__near DNameNode ( NodeType );
#endif // NO_VIRTUAL
__near DNameNode ( const DNameNode & );
public:
virtual int __near length () const PURE;
virtual pchar_t __near getString ( pchar_t, int ) const PURE;
DNameNode * __near clone ();
DNameNode * __near nextNode () const;
DNameNode & __near operator += ( DNameNode * );
};
class charNode : public DNameNode
{
private:
char me;
public:
__near charNode ( char );
virtual int __near length () const;
virtual pchar_t __near getString ( pchar_t, int ) const;
};
class pcharNode : public DNameNode
{
private:
pchar_t me;
int myLen;
public:
__near pcharNode ( pcchar_t, int = 0 );
virtual int __near length () const;
virtual pchar_t __near getString ( pchar_t, int ) const;
};
class pDNameNode : public DNameNode
{
private:
DName * me;
public:
__near pDNameNode ( DName * );
virtual int __near length () const;
virtual pchar_t __near getString ( pchar_t, int ) const;
};
class DNameStatusNode : public DNameNode
{
private:
#define TruncationMessage (" ?? ")
#define TruncationMessageLength (4)
DNameStatus me;
int myLen;
public:
__near DNameStatusNode ( DNameStatus );
virtual int __near length () const;
virtual pchar_t __near getString ( pchar_t, int ) const;
};
// Memory allocation functions
inline void __far * __near __pascal operator new ( size_t sz, HeapManager &, int noBuffer )
{ return heap.getMemory ( sz, noBuffer ); }
void __far * __near HeapManager::getMemory ( size_t sz, int noBuffer )
{
FTRACE(HeapManager::getMemory);
// Align the allocation on an appropriate boundary
sz = (( sz + PACK_SIZE ) & ~PACK_SIZE );
if ( noBuffer )
{
#if STDEBUG
actual += sz;
#endif // STDEBUG
#if ( !USE_CRT_HEAP )
return ( *pOpNew )( sz );
#else // } elif USE_CRT_HEAP {
return malloc ( sz );
#endif // USE_CRT_HEAP
} // End of IF then
else
{
// Handler a potential request for no space
if ( !sz )
sz = 1;
#if STDEBUG
requested += sz;
#endif // STDEBUG
if ( blockLeft < sz )
{
// Is the request greater than the largest buffer size ?
if ( sz > memBlockSize )
return 0; // If it is, there is nothing we can do
// Allocate a new block
Block * pNewBlock = rnew Block;
// Did the allocation succeed ? If so connect it up
if ( pNewBlock )
{
// Handle the initial state
if ( tail )
tail = tail->next = pNewBlock;
else
head = tail = pNewBlock;
// Compute the remaining space
blockLeft = memBlockSize - sz;
} // End of IF then
else
return 0; // Oh-oh! Memory allocation failure
} // End of IF then
else
blockLeft -= sz; // Deduct the allocated amount
// And return the buffer address
return &( tail->memBlock[ blockLeft ]);
} // End of IF else
} // End of "HeapManager" FUNCTION "getMemory(unsigned int,int)"
// Friend functions of 'DName'
DName __near __pascal operator + ( char c, const DName & rd )
{ return DName ( c ) + rd; }
DName __near __pascal operator + ( DNameStatus st, const DName & rd )
{ return DName ( st ) + rd; }
DName __near __pascal operator + ( pcchar_t s, const DName & rd )
{ return DName ( s ) + rd; }
// The 'DName' constructors
inline_p3 __near DName::DName () { node = 0; stat = DN_valid; isIndir = 0; isAUDC = 0; }
inline __near DName::DName ( DNameNode * pd ) { node = pd; stat = DN_valid; isIndir = 0; isAUDC = 0; }
__near DName::DName ( char c )
{
FTRACE(DName::DName(char));
stat = DN_valid;
isIndir = 0;
isAUDC = 0;
node = 0;
// The NULL character is boring, do not copy
if ( c )
doPchar ( &c, 1 );
} // End of "DName" CONSTRUCTOR '(char)'
#if 1
__near DName::DName ( const DName & rd )
{
#if STDEBUG
FTRACE(DName::DName(const DName&));
shallowCopies++;
#endif // STDEBUG
stat = rd.stat;
isIndir = rd.isIndir;
isAUDC = rd.isAUDC;
node = rd.node;
} // End of "DName" CONSTRUCTOR '(const DName&)'
#endif
#if ( !VERS_P3 )
__near DName::DName ( DName * pd )
{
FTRACE(DName::DName(DName*));
if ( pd )
{
node = gnew pDNameNode ( pd );
stat = ( node ? DN_valid : ERROR );
} // End of IF else
else
{
stat = DN_valid;
node = 0;
} // End of IF else
isIndir = 0;
isAUDC = 0;
} // End of "DName" CONSTRUCTOR '( DName* )'
#endif // !VERS_P3
__near DName::DName ( pcchar_t s )
{
FTRACE(DName::DName(pcchar_t));
stat = DN_valid;
node = 0;
isIndir = 0;
isAUDC = 0;
if ( s )
doPchar ( s, strlen ( s ));
} // End of "DName" CONSTRUCTOR '(pcchar_t)'
__near DName::DName ( pcchar_t & name, char terminator )
{
FTRACE(DName::DName(pcchar_t&,char));
stat = DN_valid;
isIndir = 0;
isAUDC = 0;
node = 0;
// Is there a string ?
if ( name )
if ( *name )
{
int len = 0;
// How long is the string ?
for ( pcchar_t s = name; *name && ( *name != terminator ); name++ )
if ( isValidIdentChar ( *name ))
len++;
else
{
stat = DN_invalid;
return;
} // End of IF else
// Copy the name string fragment
doPchar ( s, len );
// Now gobble the terminator if present, handle error conditions
if ( *name )
{
if ( *name++ != terminator )
{
stat = ERROR;
node = 0;
} // End of IF then
else
stat = DN_valid;
} // End of IF then
elif ( status () == DN_valid )
stat = DN_truncated;
} // End of IF then
else
stat = DN_truncated;
else
stat = DN_invalid;
} // End of "DName" CONSTRUCTOR '(pcchar_t&,char)'
#if ( !VERS_P3 )
__near DName::DName ( unsigned long num )
{
FTRACE(DName::DName(unsigned long));
char buf[ 11 ];
char * pBuf = buf + 10;
stat = DN_valid;
node = 0;
isIndir = 0;
isAUDC = 0;
// Essentially, 'ultoa ( num, buf, 10 )' :-
*pBuf = 0;
do
{
*( --pBuf ) = (char)(( num % 10 ) + '0' );
num /= 10UL;
} while ( num );
doPchar ( pBuf, ( 10 - (int)( pBuf - buf )));
} // End of "DName" CONSTRUCTOR '(unsigned long)'
#endif // !VERS_P3
__near DName::DName ( DNameStatus st )
{
FTRACE(DName::DName(DNameStatus));
stat = ((( st == DN_invalid ) || ( st == DN_error )) ? st : DN_valid );
node = gnew DNameStatusNode ( st );
isIndir = 0;
isAUDC = 0;
if ( !node )
stat = ERROR;
} // End of "DName" CONSTRUCTOR '(DNameStatus)'
// Now the member functions for 'DName'
int __near DName::isValid () const { return (( status () == DN_valid ) || ( status () == DN_truncated )); }
int __near DName::isEmpty () const { return (( node == 0 ) || !isValid ()); }
inline DNameStatus __near DName::status () const { return (DNameStatus)stat; } // The cast is to keep Glockenspiel quiet
#if ( !VERS_P3 )
inline DName & __near DName::setPtrRef () { isIndir = 1; return *this; }
inline int __near DName::isPtrRef () const { return isIndir; }
inline int __near DName::isUDC () const { return ( !isEmpty () && isAUDC ); }
inline void __near DName::setIsUDC () { if ( !isEmpty ()) isAUDC = TRUE; }
#endif // !VERS_P3
int __near DName::length () const
{
FTRACE(DName::length);
int len = 0;
if ( !isEmpty ())
for ( DNameNode * pNode = node; pNode; pNode = pNode->nextNode ())
len += pNode->length ();
return len;
} // End of "DName" FUNCTION "length"
pchar_t __near DName::getString ( pchar_t buf, int max ) const
{
FTRACE(DName::getString);
if ( !isEmpty ())
{
// Does the caller want a buffer allocated ?
if ( !buf )
{
max = length () + 1;
buf = gnew char[ max ]; // Get a buffer big enough
} // End of IF then
// If memory allocation failure, then return no buffer
if ( buf )
{
// Now, go through the process of filling the buffer (until max is reached)
int curLen = max;
DNameNode * curNode = node;
pchar_t curBuf = buf;
while ( curNode && ( curLen > 0 ))
{
int fragLen = curNode->length ();
pchar_t fragBuf = 0;
// Skip empty nodes
if ( fragLen )
{
// Handle buffer overflow
if (( curLen - fragLen ) < 0 )
fragLen = curLen;
// Now copy 'len' number of bytes of the piece to the buffer
fragBuf = curNode->getString ( curBuf, fragLen );
// Should never happen, but handle it anyway
if ( fragBuf )
{
// Update string position
curLen -= fragLen;
curBuf += fragLen;
} // End of IF
} // End of IF
// Move on to the next name fragment
curNode = curNode->nextNode ();
} // End of WHILE
*curBuf = 0; // Always NULL terminate the resulting string
} // End of IF
} // End of IF then
elif ( buf )
*buf = 0;
// Return the buffer
return buf;
} // End of "DName" FUNCTION "getString(pchar_t,int)"
#if ( !VERS_P3 )
DName __near DName::operator + ( char ch ) const
{
FTRACE(DName::+(char));
DName local ( *this );
if ( local.isEmpty ())
local = ch;
else
local += ch;
// And return the newly formed 'DName'
return local;
} // End of "DName" OPERATOR "+(char)"
#endif // !VERS_P3
DName __near DName::operator + ( pcchar_t str ) const
{
FTRACE(DName::+(pcchar_t));
DName local ( *this );
if ( local.isEmpty ())
local = str;
else
local += str;
// And return the newly formed 'DName'
return local;
} // End of "DName" OPERATOR "+(pcchar_t)"
DName __near DName::operator + ( const DName & rd ) const
{
FTRACE(DName::+(const DName&));
DName local ( *this );
if ( local.isEmpty ())
local = rd;
elif ( rd.isEmpty ())
local += rd.status ();
else
local += rd;
// And return the newly formed 'DName'
return local;
} // End of "DName" OPERATOR "+(const DName&)"
#if ( !VERS_P3 )
DName __near DName::operator + ( DName * pd ) const
{
FTRACE(DName::+(DName*));
DName local ( *this );
if ( local.isEmpty ())
local = pd;
else
local += pd;
// And return the newly formed 'DName'
return local;
} // End of "DName" OPERATOR "+(DName*)"
DName __near DName::operator + ( DNameStatus st ) const
{
FTRACE(DName::+(DNameStatus));
DName local ( *this );
if ( local.isEmpty ())
local = st;
else
local += st;
// And return the newly formed 'DName'
return local;
} // End of "DName" OPERATOR "+(DNameStatus)"
DName & __near DName::operator += ( char ch )
{
FTRACE(DName::+=(char));
if ( ch )
if ( isEmpty ())
*this = ch;
else
{
node = node->clone ();
if ( node )
*node += gnew charNode ( ch );
else
stat = ERROR;
} // End of IF
// And return self
return *this;
} // End of "DName" OPERATOR "+=(char)"
DName & __near DName::operator += ( pcchar_t str )
{
FTRACE(DName::+=(pcchar_t));
if ( str && *str )
if ( isEmpty ())
*this = str;
else
{
node = node->clone ();
if ( node )
*node += gnew pcharNode ( str );
else
stat = ERROR;
} // End of IF
// And return self
return *this;
} // End of "DName" OPERATOR "+=(pcchar_t)"
#endif // !VERS_P3
DName & __near DName::operator += ( const DName & rd )
{
FTRACE(DName::+=(const DName&));
if ( rd.isEmpty ())
*this += rd.status ();
else
if ( isEmpty ())
*this = rd;
else
{
node = node->clone ();
if ( node )
*node += rd.node;
else
stat = ERROR;
} // End of IF
// And return self
return *this;
} // End of "DName" OPERATOR "+=(const DName&)"
#if ( !VERS_P3 )
DName & __near DName::operator += ( DName * pd )
{
FTRACE(DName::+=(DName*));
if ( pd )
if ( isEmpty ())
*this = pd;
elif (( pd->status () == DN_valid ) || ( pd->status () == DN_truncated ))
{
DNameNode * pNew = gnew pDNameNode ( pd );
if ( pNew )
{
node = node->clone ();
if ( node )
*node += pNew;
} // End of IF then
else
node = 0;
if ( !node )
stat = ERROR;
} // End of IF then
else
*this += pd->status ();
// And return self
return *this;
} // End of "DName" OPERATOR "+=(DName*)"
DName & __near DName::operator += ( DNameStatus st )
{
FTRACE(DName::+=(DNameStatus));
if ( isEmpty () || (( st == DN_invalid ) || ( st == DN_error )))
*this = st;
else
{
DNameNode * pNew = gnew DNameStatusNode ( st );
if ( pNew )
{
node = node->clone ();
if ( node )
*node += pNew;
} // End of IF then
else
node = 0;
if ( !node )
stat = ERROR;
} // End of IF else
// Return self
return *this;
} // End of "DName" OPERATOR "+=(DNameStatus)"
DName & __near DName::operator |= ( const DName & rd )
{
FTRACE(DName::=(const DName&));
// Attenuate the error status. Always becomes worse. Don't propogate truncation
if (( status () != DN_error ) && !rd.isValid ())
stat = rd.status ();
// And return self
return *this;
} // End of "DName" OPERATOR '|=(const DName&)'
DName & __near DName::operator = ( char ch )
{
FTRACE(DName::=(char));
isIndir = 0;
isAUDC = 0;
doPchar ( &ch, 1 );
return *this;
} // End of "DName" OPERATOR '=(char)'
#endif // !VERS_P3
DName & __near DName::operator = ( pcchar_t str )
{
FTRACE(DName::=(pcchar_t));
isIndir = 0;
isAUDC = 0;
doPchar ( str, strlen ( str ));
// And return self
return *this;
} // End of "DName" OPERATOR '=(pcchar_t)'
DName & __near DName::operator = ( const DName & rd )
{
FTRACE(DName::=(const DName&));
if (( status () == DN_valid ) || ( status () == DN_truncated ))
{
#if STDEBUG
shallowAssigns++;
#endif // STDEBUG
stat = rd.stat;
isIndir = rd.isIndir;
isAUDC = rd.isAUDC;
node = rd.node;
} // End of IF
// And return self
return *this;
} // End of "DName" OPERATOR '=(const DName&)'
#if ( !VERS_P3 )
DName & __near DName::operator = ( DName * pd )
{
FTRACE(DName::=(DName*));
if (( status () == DN_valid ) || ( status () == DN_truncated ))
if ( pd )
{
isIndir = 0;
isAUDC = 0;
node = gnew pDNameNode ( pd );
if ( !node )
stat = ERROR;
} // End of IF then
else
*this = ERROR;
// And return self
return *this;
} // End of "DName" OPERATOR '=(DName*)'
DName & __near DName::operator = ( DNameStatus st )
{
FTRACE(DName::=(DNameStatus));
if (( st == DN_invalid ) || ( st == DN_error ))
{
node = 0;
if ( status () != DN_error )
stat = st;
} // End of IF then
elif (( status () == DN_valid ) || ( status () == DN_truncated ))
{
isIndir = 0;
isAUDC = 0;
node = gnew DNameStatusNode ( st );
if ( !node )
stat = ERROR;
} // End of ELIF then
// And return self
return *this;
} // End of "DName" OPERATOR '=(DNameStatus)'
#endif // !VERS_P3
// Private implementation functions for 'DName'
void __near DName::doPchar ( pcchar_t str, int len )
{
FTRACE(DName::doPchar);
if ( !(( status () == DN_invalid ) || ( status () == DN_error )))
if ( node )
*this = ERROR;
elif ( str && len )
{
// Allocate as economically as possible
switch ( len )
{
case 0:
stat = ERROR;
break;
case 1:
node = gnew charNode ( *str );
if ( !node )
stat = ERROR;
break;
default:
node = gnew pcharNode ( str, len );
if ( !node )
stat = ERROR;
break;
} // End of SWITCH
} // End of ELIF
else
stat = DN_invalid;
} // End of "DName" FUNCTION "doPchar(pcchar_t,int)"
// The member functions for the 'Replicator'
inline int __near Replicator::isFull () const { return ( index == 9 ); }
inline __near Replicator::Replicator ()
: ErrorDName ( DN_error ), InvalidDName ( DN_invalid )
{ index = -1; }
Replicator & __near Replicator::operator += ( const DName & rd )
{
FTRACE(Replicator::+=);
if ( !isFull () && !rd.isEmpty ())
{
DName * pNew = gnew DName ( rd );
// Don't update if failed
if ( pNew )
dNameBuffer[ ++index ] = pNew;
} // End of IF
return *this;
} // End of "Replicator" OPERATOR '+=(const DName&)'
const DName & __near Replicator::operator [] ( int x ) const
{
FTRACE(Replicator::[]);
if (( x < 0 ) || ( x > 9 ))
return ErrorDName;
elif (( index == -1 ) || ( x > index ))
{
(void)ERROR;
return InvalidDName;
} // End of ELIF then
else
return *dNameBuffer[ x ];
} // End of "Replicator" OPERATOR '[](int)'
// The member functions for the 'DNameNode' classes
#if ( !NO_VIRTUAL )
__near DNameNode::DNameNode ()
#else // } elif NO_VIRTUAL {
__near DNameNode::DNameNode ( NodeType ndTy )
: typeIndex ( ndTy )
#endif // NO_VIRTUAL
{ next = 0; }
inline __near DNameNode::DNameNode ( const DNameNode & rd ) { next = (( rd.next ) ? rd.next->clone () : 0 ); }
inline DNameNode * __near DNameNode::nextNode () const { return next; }
DNameNode * __near DNameNode::clone ()
{
#if STDEBUG
FTRACE(DNameNode::clone);
clones++;
#endif // STDEBUG
return gnew pDNameNode ( gnew DName ( this ));
}
#if ( STDEBUG || NO_VIRTUAL )
int __near DNameNode::length () const
{ // Pure function, should not be called
FTRACE(DNameNode::length);
#if ( NO_VIRTUAL )
switch ( typeIndex )
{
case charNode_t:
return ((charNode*)this )->length ();
case pcharNode_t:
return ((pcharNode*)this )->length ();
case pDNameNode_t:
return ((pDNameNode*)this )->length ();
case DNameStatusNode_t:
return ((DNameStatusNode*)this )->length ();
} // End of SWITCH
#endif // NO_VIRTUAL
return 0;
}
pchar_t __near DNameNode::getString ( pchar_t s, int l ) const
{ // Pure function, should not be called
FTRACE(DNameNode::getString);
#if ( NO_VIRTUAL )
switch ( typeIndex )
{
case charNode_t:
return ((charNode*)this )->getString ( s, l );
case pcharNode_t:
return ((pcharNode*)this )->getString ( s, l );
case pDNameNode_t:
return ((pDNameNode*)this )->getString ( s, l );
case DNameStatusNode_t:
return ((DNameStatusNode*)this )->getString ( s, l );
} // End of SWITCH
#endif // NO_VIRTUAL
return 0;
}
#endif // STDEBUG || NO_VIRTUAL
DNameNode & __near DNameNode::operator += ( DNameNode * pNode )
{
FTRACE(DNameNode::+=(DNameNode*));
if ( pNode )
{
if ( next )
{
// Skip to the end of the chain
for ( DNameNode* pScan = next; pScan->next; pScan = pScan->next )
;
// And append the new node
pScan->next = pNode;
} // End of IF then
else
next = pNode;
} // End of IF
// And return self
return *this;
} // End of "DNameNode" OPERATOR '+=(DNameNode*)'
// The 'charNode' virtual functions
inline_p3 __near charNode::charNode ( char ch )
#if ( NO_VIRTUAL )
: DNameNode ( charNode_t )
#endif // NO_VIRTUAL
{ me = ch; }
inline int __near charNode::length () const { return 1; }
inline_pwb
inline_lnk
pchar_t __near charNode::getString ( pchar_t buf, int len ) const
{
FTRACE(charNode::getString);
if ( buf && len )
*buf = me;
else
buf = 0;
// Now return the character
return buf;
} // End of "charNode" FUNCTION "getString(pchar_t,int)"
// The 'pcharNode' virtual functions
inline int __near pcharNode::length () const { return myLen; }
__near pcharNode::pcharNode ( pcchar_t str, int len )
#if ( NO_VIRTUAL )
: DNameNode ( pcharNode_t )
#endif // NO_VIRTUAL
{
FTRACE(pcharNode::pcharNode);
// Get length if not supplied
if ( !len && str )
len = strlen ( str );
// Allocate a new string buffer if valid state
if ( len && str )
{
me = gnew char[ len ];
myLen = len;
if ( me )
strncpy ( me, str, len );
} // End of IF then
else
{
me = 0;
myLen = 0;
} // End of IF else
} // End of "pcharNode" CONSTRUCTOR '(pcchar_t,int)'
inline_pwb
inline_lnk
pchar_t __near pcharNode::getString ( pchar_t buf, int len ) const
{
FTRACE(pcharNode::getString);
// Use the shorter of the two lengths (may not be NULL terminated)
if ( len > pcharNode::length ())
len = pcharNode::length ();
// Do the copy as appropriate
return (( me && buf && len ) ? strncpy ( buf, me, len ) : 0 );
} // End of "pcharNode" FUNCTION "getString(pchar_t,int)"
// The 'pDNameNode' virtual functions
inline_p3 __near pDNameNode::pDNameNode ( DName * pName )
#if ( NO_VIRTUAL )
: DNameNode ( pDNameNode_t )
#endif // NO_VIRTUAL
{ me = (( pName && (( pName->status () == DN_invalid ) || ( pName->status () == DN_error ))) ? 0 : pName ); }
inline int __near pDNameNode::length () const { return ( me ? me->length () : 0 ); }
inline_pwb
inline_lnk
pchar_t __near pDNameNode::getString ( pchar_t buf, int len ) const
{ return (( me && buf && len ) ? me->getString ( buf, len ) : 0 ); }
// The 'DNameStatusNode' virtual functions
inline_p3 __near DNameStatusNode::DNameStatusNode ( DNameStatus stat )
#if ( NO_VIRTUAL )
: DNameNode ( DNameStatusNode_t )
#endif // NO_VIRTUAL
{ me = stat; myLen = (( me == DN_truncated ) ? TruncationMessageLength : 0 ); }
inline int __near DNameStatusNode::length () const { return myLen; }
inline_pwb
inline_lnk
pchar_t __near DNameStatusNode::getString ( pchar_t buf, int len ) const
{
FTRACE(DNameStatusNode::getString);
// Use the shorter of the two lengths (may not be NULL terminated)
if ( len > DNameStatusNode::length ())
len = DNameStatusNode::length ();
// Do the copy as appropriate
return ((( me == DN_truncated ) && buf && len ) ? strncpy ( buf, TruncationMessage, len ) : 0 );
} // End of "DNameStatusNode" FUNCTION "getString(pchar_t,int)"
static unsigned int __near __pascal strlen ( pcchar_t str )
{
for ( unsigned int len = 0; *str; str++ )
len++;
return len;
} // End of FUNCTION "strlen"
static pchar_t __near __pascal strncpy ( pchar_t dst, pcchar_t src, unsigned int len )
{
for ( char __far * d = dst; ( len && ( *d = *src )); d++, src++, len-- )
;
return dst;
} // End of FUNCTION "strncpy"
#if STDEBUG
void CallTrace::Dump ( const DName & rd, pcchar_t sym, int line )
{
if ( trace && !inTrace )
{
inTrace = 1;
rd.getString ( buf, 512 );
buf[ rd.length ()] = 0;
indent ( mark );
fprintf ( fp, " > DName '%s' #%d: '%s' == '%s'\n", name, line, sym, buf );
fflush ( fp );
inTrace = 0;
}
}
void CallTrace::Dump ( const DNameNode & rd, pcchar_t sym, int line )
{
if ( trace && !inTrace )
{
inTrace = 1;
rd.getString ( buf, 512 );
buf[ rd.length ()] = 0;
indent ( mark );
fprintf ( fp, " > DNameNode '%s' #line %d : '%s' == '%s'\n", name, line, sym, buf );
fflush ( fp );
inTrace = 0;
}
}
void CallTrace::Dump ( unsigned long ul, pcchar_t sym, int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > ulong '%s' #line %d : '%s' == '0x%08.08LX'\n", name, line, sym, ul );
fflush ( fp );
}
}
void CallTrace::Dump ( void* p, pcchar_t sym, int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > void* '%s' #line %d : '%s' == '%p'\n", name, line, sym, p );
fflush ( fp );
}
}
void CallTrace::Dump ( const char* p, pcchar_t sym, int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > char* '%s' #line %d : '%s' == '%s'\n", name, line, sym, p );
fflush ( fp );
}
}
void CallTrace::Track ( pcchar_t file, int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > Track '%s' : #line %d \"%s\"\n", name, line, file );
fflush ( fp );
}
}
void CallTrace::LogError ( int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > Log Error '%s' : #line %d\n", name, line );
fflush ( fp );
}
}
void CallTrace::Message ( pcchar_t msg, int line )
{
if ( trace )
{
indent ( mark );
fprintf ( fp, " > Message '%s' : #line %d \"%s\"\n", name, line, msg );
fflush ( fp );
}
}
#endif // STDEBUG