Source code of Windows XP (NT5)
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/*++
Copyright (C) 1999 Microsoft Corporation
Module Name:
OBJPATH.CPP
Abstract:
Object path parser.
History:
--*/
#include <windows.h>
#include <stdio.h>
#include <oleauto.h>
#include <genlex.h>
#include <opathlex.h>
#include "objpath.h"
inline WCHAR* Macro_CloneLPWSTR(const WCHAR* x)
{
if (x == NULL)
{
return NULL;
}
WCHAR* pwszRet = new wchar_t[wcslen(x) + 1];
if (pwszRet)
{
wcscpy(pwszRet, x);
}
return pwszRet;
}
const DWORD ParsedObjectPath::m_scdwAllocNamespaceChunkSize = 2;
const DWORD ParsedObjectPath::m_scdwAllocKeysChunkSize = 2;
ParsedObjectPath::ParsedObjectPath()
{
unsigned int i;
m_pServer = 0; // NULL if no server
m_dwNumNamespaces = 0; // 0 if no namespaces
m_dwAllocNamespaces = 0; // Initialize to 0, assuming m_paNamespaces allocation will fail
m_paNamespaces = new LPWSTR[m_scdwAllocNamespaceChunkSize];
if (NULL != m_paNamespaces)
{
m_dwAllocNamespaces = m_scdwAllocNamespaceChunkSize;
for (i = 0; i < m_dwAllocNamespaces; i++)
m_paNamespaces[i] = 0;
}
m_pClass = 0; // Class name
m_dwNumKeys = 0; // 0 if no keys (just a class name)
m_bSingletonObj = FALSE;
m_dwAllocKeys = 0; // Initialize to 0, assuming m_paKeys allocation will fail
m_paKeys = new KeyRef *[m_scdwAllocKeysChunkSize];
if (NULL != m_paKeys)
{
m_dwAllocKeys = m_scdwAllocKeysChunkSize;
for (i = 0; i < m_dwAllocKeys; i++)
m_paKeys[i] = 0;
}
}
ParsedObjectPath::~ParsedObjectPath()
{
delete m_pServer;
for (DWORD dwIx = 0; dwIx < m_dwNumNamespaces; dwIx++)
delete m_paNamespaces[dwIx];
delete [] m_paNamespaces;
delete m_pClass;
for (dwIx = 0; dwIx < m_dwNumKeys; dwIx++)
delete m_paKeys[dwIx];
delete [] m_paKeys;
}
BOOL ParsedObjectPath::SetClassName(LPCWSTR wszClassName)
{
delete [] m_pClass;
if(wszClassName == NULL)
{
m_pClass = NULL;
}
else
{
m_pClass = Macro_CloneLPWSTR(wszClassName);
if (NULL == m_pClass)
return FALSE;
}
return TRUE;
}
// ChrisDar 20 March 2001
// Keeping IsClass in code for now, but it appears to be dead code. It is not called
// by any method in the wlbs code tree except IsInstance, which is not called by any method.
BOOL ParsedObjectPath::IsClass()
{
if(!IsObject())
return FALSE;
return (m_dwNumKeys == 0 && !m_bSingletonObj);
}
// ChrisDar 20 March 2001
// Keeping IsInstance in code for now, but it appears to be dead code. It is not called
// by any method in the wlbs code tree except IsInstance, which is not called by any method.
BOOL ParsedObjectPath::IsInstance()
{
return IsObject() && !IsClass();
}
// ChrisDar 20 March 2001
// Keeping IsObject in code for now, but it appears to be dead code. It is not called
// by any method in the wlbs code tree except IsInstance, which is not called by any method.
BOOL ParsedObjectPath::IsObject()
{
if(m_pClass == NULL)
return FALSE;
if(m_pServer)
{
return (m_dwNumNamespaces > 0);
}
else
{
return (m_dwNumNamespaces == 0);
}
}
BOOL ParsedObjectPath::AddNamespace(LPCWSTR wszNamespace)
{
if (NULL == wszNamespace || 0 == *wszNamespace)
return FALSE;
if(0 == m_dwAllocNamespaces || m_dwNumNamespaces == m_dwAllocNamespaces)
{
// Here if array is full or allocation failed previously
DWORD dwNewAllocNamespaces = 0;
if (0 == m_dwAllocNamespaces)
{
dwNewAllocNamespaces = m_scdwAllocNamespaceChunkSize;
}
else
{
dwNewAllocNamespaces = m_dwAllocNamespaces * 2;
}
LPWSTR* paNewNamespaces = new LPWSTR[dwNewAllocNamespaces];
if (paNewNamespaces == NULL)
{
return FALSE;
}
unsigned int i = 0;
// Initialize the array to NULLs
for (i = 0; i < dwNewAllocNamespaces; i++)
paNewNamespaces[i] = 0;
if (NULL != m_paNamespaces)
{
// Here only if we previously had an allocation success
memcpy(paNewNamespaces, m_paNamespaces,
sizeof(LPWSTR) * m_dwNumNamespaces);
delete [] m_paNamespaces;
}
m_paNamespaces = paNewNamespaces;
m_dwAllocNamespaces = dwNewAllocNamespaces;
}
m_paNamespaces[m_dwNumNamespaces] = Macro_CloneLPWSTR(wszNamespace);
if (NULL == m_paNamespaces[m_dwNumNamespaces])
return FALSE;
m_dwNumNamespaces++;
return TRUE;
}
// ChrisDar 20 March 2001
// Keeping AddKeyRefEx in code for now, but it appears to be dead code. It is not called
// by any method in the wlbs code tree.
// ChrisDar 22 March 2001
// This really needs to be modified to return more info than pass/fail. Should reflect enums in CObjectPathParser
BOOL ParsedObjectPath::AddKeyRefEx(LPCWSTR wszKeyName, const VARIANT* pvValue )
{
// ChrisDar 20 March 2001
// Notes:
// 1. wszKeyName is allowed to be NULL. It acts as a signal to remove all existing keys,
// then add an unnamed key with this value. It is unclear why removing all keys is required.
// Perhaps this supports only one key when the key is unnamed...
// 2. This code is riddled with places where memory allocations could screw up state. Some are
// "new"s while there are also calls to VariantCopy.
// 3. VariantClear and VariantCopy have return values and they are not being checked.
// 4. AddKeyRef can fail but it being called without checking the return value.
// 5. Apparently pvValue must be non-NULL, but it isn't being validated before being dereferenced.
// 6. bStatus is for the return value but it is never modified. Changed to return TRUE;.
BOOL bStatus = TRUE ;
BOOL bFound = FALSE ;
BOOL bUnNamed = FALSE ;
for ( ULONG dwIndex = 0 ; dwIndex < m_dwNumKeys ; dwIndex ++ )
{
if ( ( m_paKeys [ dwIndex ]->m_pName ) && wszKeyName )
{
if ( _wcsicmp ( m_paKeys [ dwIndex ]->m_pName , wszKeyName )
== 0 )
{
bFound = TRUE ;
break ;
}
}
else
{
if ( ( ( m_paKeys [ dwIndex ]->m_pName ) == 0 ) )
{
bUnNamed = TRUE ;
if ( ( wszKeyName == 0 ) )
{
bFound = TRUE ;
break ;
}
}
}
}
if ( ! wszKeyName )
{
/* Remove all existing keys */
for ( ULONG dwDeleteIndex = 0 ; dwDeleteIndex < m_dwNumKeys ;
dwDeleteIndex ++ )
{
delete ( m_paKeys [ dwDeleteIndex ]->m_pName ) ;
m_paKeys [ dwDeleteIndex ]->m_pName = NULL ;
VariantClear ( & ( m_paKeys [ dwDeleteIndex ]->m_vValue ) ) ;
}
VariantCopy ( & ( m_paKeys [ 0 ]->m_vValue ) , ( VARIANT * ) pvValue );
m_dwNumKeys = 1 ;
}
else
{
if ( bFound )
{
/*
* If key already exists then just replace the value
*/
if ( wszKeyName )
{
m_paKeys [ dwIndex ]->m_pName =
new wchar_t [ wcslen ( wszKeyName ) + 1 ] ;
wcscpy ( m_paKeys [ dwIndex ]->m_pName , wszKeyName ) ;
}
VariantClear ( & ( m_paKeys [ dwIndex ]->m_vValue ) ) ;
VariantCopy ( & ( m_paKeys [ dwIndex ]->m_vValue ) ,
( VARIANT * ) pvValue ) ;
}
else
{
if ( bUnNamed )
{
/* Add an un named key */
for ( ULONG dwDeleteIndex = 0 ; dwDeleteIndex < m_dwNumKeys ;
dwDeleteIndex ++ )
{
delete ( m_paKeys [ dwDeleteIndex ]->m_pName ) ;
m_paKeys [ dwDeleteIndex ]->m_pName = NULL ;
VariantClear (& ( m_paKeys [ dwDeleteIndex ]->m_vValue ) );
}
m_paKeys [ 0 ]->m_pName =
new wchar_t [ wcslen ( wszKeyName ) + 1 ] ;
wcscpy ( m_paKeys [ 0 ]->m_pName , wszKeyName ) ;
VariantCopy ( & ( m_paKeys [ 0 ]->m_vValue ) ,
( VARIANT * ) pvValue ) ;
m_dwNumKeys = 1 ;
}
else
{
/* Add a Named Key */
AddKeyRef(wszKeyName, pvValue);
}
}
}
return bStatus;
}
void ParsedObjectPath::ClearKeys ()
{
for ( ULONG dwDeleteIndex = 0 ; dwDeleteIndex < m_dwNumKeys ;
dwDeleteIndex ++ )
{
delete m_paKeys [ dwDeleteIndex ] ;
m_paKeys [ dwDeleteIndex ] = NULL ;
}
delete [] m_paKeys ;
m_paKeys = NULL ;
m_dwNumKeys = 0; // 0 if no keys (just a class name)
m_dwAllocKeys = 0; // Initialize to 0, assuming m_paKeys allocation will fail
m_paKeys = new KeyRef *[m_scdwAllocKeysChunkSize];
if (NULL != m_paKeys)
{
m_dwAllocKeys = m_scdwAllocKeysChunkSize;
for (unsigned int i = 0; i < m_dwAllocKeys; i++)
m_paKeys[i] = 0;
}
}
// ChrisDar 22 March 2001
// This really needs to be modified to return more info than pass/fail. Should reflect enums in CObjectPathParser
BOOL ParsedObjectPath::AddKeyRef(LPCWSTR wszKeyName, const VARIANT* pvValue)
{
// Unnamed keys are allowed, i.e., NULL == wszKeyName. But pvValue must be valid.
if (NULL == pvValue)
return FALSE;
if(0 == m_dwAllocKeys || m_dwNumKeys == m_dwAllocKeys)
{
if (!IncreaseNumAllocKeys())
return FALSE;
}
m_paKeys[m_dwNumKeys] = new KeyRef(wszKeyName, pvValue);
if (NULL == m_paKeys[m_dwNumKeys])
return FALSE;
m_dwNumKeys++;
return TRUE;
}
// ChrisDar 22 March 2001
// This really needs to be modified to return more info than pass/fail. Should reflect enums in CObjectPathParser
BOOL ParsedObjectPath::AddKeyRef(KeyRef* pAcquireRef)
{
if (NULL == pAcquireRef)
return FALSE;
if(0 == m_dwAllocKeys || m_dwNumKeys == m_dwAllocKeys)
{
if (!IncreaseNumAllocKeys())
return FALSE;
}
m_paKeys[m_dwNumKeys] = pAcquireRef;
m_dwNumKeys++;
return TRUE;
}
KeyRef::KeyRef()
{
m_pName = 0;
VariantInit(&m_vValue);
}
KeyRef::KeyRef(LPCWSTR wszKeyName, const VARIANT* pvValue)
{
// An unnamed key (wszKeyName is NULL) is legal, but pvValue can't be NULL.
if (NULL == pvValue)
{
// Our input argument is invalid. What do we do? For now, throw a generic WBEM exception
throw _com_error(WBEM_E_FAILED);
}
m_pName = Macro_CloneLPWSTR(wszKeyName);
if (NULL != wszKeyName && NULL == m_pName)
{
// Memory allocation failed. We can't fail the call since we are in a constructor, so throw exception.
throw _com_error(WBEM_E_OUT_OF_MEMORY);
}
VariantInit(&m_vValue);
HRESULT hr = VariantCopy(&m_vValue, (VARIANT*)pvValue);
if (S_OK != hr)
{
// What do we do? Throw WBEM exception for now.
WBEMSTATUS ws = WBEM_E_FAILED;
if (E_OUTOFMEMORY == hr)
ws = WBEM_E_OUT_OF_MEMORY;
throw _com_error(ws);
}
}
KeyRef::~KeyRef()
{
delete m_pName;
// No check of return value here since we are destroying the object.
VariantClear(&m_vValue);
}
int WINAPI CObjectPathParser::Unparse(
ParsedObjectPath* pInput,
DELETE_ME LPWSTR* pwszPath)
{
// ChrisDar 20 March 2001
// I AM CONCERNED ABOUT THE "DELETE_ME" IN THE ARG OF CALL. #define'd IN OBJPATH.H TO "". REMOVE IT?
// This is a confusing method. pInput must be a valid pointer. pwszPath MUST be a valid pointer initialized to NULL.
// This method's job is to allocate a path as a string and pass it back to the caller
// in pwszPath. It needs pInput to determine the path.
if (NULL == pInput || pInput->m_pClass == NULL)
{
return CObjectPathParser::InvalidParameter;
}
// Allocate enough space
// =====================
int nSpace = wcslen(pInput->m_pClass);
nSpace += 10;
DWORD dwIx;
for (dwIx = 0; dwIx < pInput->m_dwNumKeys; dwIx++)
{
KeyRef* pKey = pInput->m_paKeys[dwIx];
if(pKey->m_pName)
nSpace += wcslen(pKey->m_pName);
if(V_VT(&pKey->m_vValue) == VT_BSTR)
{
nSpace += wcslen(V_BSTR(&pKey->m_vValue))*2 + 10;
}
else if( V_VT(&pKey->m_vValue) == VT_I4
|| V_VT(&pKey->m_vValue) == VT_UI4 )
{
nSpace += 30;
}
else if ( V_VT(&pKey->m_vValue) == VT_I2
|| V_VT(&pKey->m_vValue) == VT_UI2 )
{
nSpace += 15;
}
else if ( V_VT(&pKey->m_vValue) == VT_I1
|| V_VT(&pKey->m_vValue) == VT_UI1 )
{
nSpace += 8;
}
}
if(pInput->m_bSingletonObj)
nSpace +=2;
WCHAR wszTemp[30];
LPWSTR wszPath = new WCHAR[nSpace];
if (NULL == wszPath)
return CObjectPathParser::OutOfMemory;
wcscpy(wszPath, pInput->m_pClass);
for (dwIx = 0; dwIx < pInput->m_dwNumKeys; dwIx++)
{
KeyRef* pKey = pInput->m_paKeys[dwIx];
// We dont want to put a '.' if there isnt a key name,
// for example, Myclass="value"
if(dwIx == 0)
{
if((pKey->m_pName && (0 < wcslen(pKey->m_pName))) || pInput->m_dwNumKeys > 1)
wcscat(wszPath, L".");
}
else
{
wcscat(wszPath, L",");
}
if(pKey->m_pName)
wcscat(wszPath, pKey->m_pName);
wcscat(wszPath, L"=");
if(V_VT(&pKey->m_vValue) == VT_BSTR)
{
wcscat(wszPath, L"\"");
WCHAR* pwc = V_BSTR(&pKey->m_vValue);
WCHAR str[2];
str[1] = 0;
while(*pwc)
{
if(*pwc == '\\' || *pwc == '"')
{
wcscat(wszPath, L"\\");
}
str[0] = *pwc;
wcscat(wszPath, str);
pwc++;
}
wcscat(wszPath, L"\"");
}
else if( V_VT(&pKey->m_vValue) == VT_I4 )
{
swprintf(wszTemp, L"%d", V_I4(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
else if( V_VT(&pKey->m_vValue) == VT_UI4 )
{
swprintf(wszTemp, L"%u", V_UI4(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
else if( V_VT(&pKey->m_vValue) == VT_I2 )
{
swprintf(wszTemp, L"%hd", V_I2(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
else if( V_VT(&pKey->m_vValue) == VT_UI2 )
{
swprintf(wszTemp, L"%hu", V_UI2(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
else if( V_VT(&pKey->m_vValue) == VT_I1 )
{
swprintf(wszTemp, L"%d", V_I1(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
else if( V_VT(&pKey->m_vValue) == VT_UI1 )
{
swprintf(wszTemp, L"%u", V_UI1(&pKey->m_vValue));
wcscat(wszPath, wszTemp);
}
}
// Take care of the singleton case. This is a path of the form
// MyClass=@ and represents a single instance of a class with no
// keys.
if(pInput->m_bSingletonObj && pInput->m_dwNumKeys == 0)
wcscat(wszPath, L"=@");
*pwszPath = wszPath;
return CObjectPathParser::NoError;
}
// ChrisDar 20 March 2001
// Keeping GetRelativePath in code for now, but it appears to be dead code. It is not called
// by any method in the wlbs code tree.
LPWSTR WINAPI CObjectPathParser::GetRelativePath(LPWSTR wszFullPath)
{
// ChrisDar 20 March 2001
// wszFullPath is no being validated before use.
LPWSTR wsz = wcschr(wszFullPath, L':');
if(wsz)
return wsz + 1;
else
return NULL;
}
void CObjectPathParser::Zero()
{
m_nCurrentToken = 0;
m_pLexer = 0;
m_pInitialIdent = 0;
m_pOutput = 0;
m_pTmpKeyRef = 0;
}
CObjectPathParser::CObjectPathParser(ObjectParserFlags eFlags)
: m_eFlags(eFlags)
{
Zero();
}
void CObjectPathParser::Empty()
{
delete m_pLexer;
m_pLexer = 0;
delete m_pInitialIdent;
m_pInitialIdent = 0;
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
// m_pOutput is intentionally left alone,
// since all code paths delete this already on error, or
// else the user acquired the pointer.
}
CObjectPathParser::~CObjectPathParser()
{
Empty();
}
int CObjectPathParser::Parse(
LPCWSTR pRawPath,
ParsedObjectPath **pOutput
)
{
// ChrisDar 20 March 2001
// This method creates a ParsedObjectPath (if possible) and passes it back to the user by pointer.
// It also ensures that the pointer is not retained within the class. It is the user's responsibiliy
// to delete the memory. It is also the user's responsibility to ensure that pOutput is a valid
// pointer that does not point to an existing instances of a ParsedObjectPath*. Otherwise, this method
// could cause a memory leak, since we overwrite the pointer.
//
// This is an extremely dangerous way to use a private data member. Other methods use m_pOutput and
// are currently only called by this method or a method that only this one calls. Though the methods
// are private, anyone maintaining the code needs to know not to use this variable or these methods
// because m_pOutput is valid only so long as this method is executing... I have changed this so that
// m_pOutput is passed among the private methods that need it. It is cumbersome but safer.
if (pOutput == 0 || pRawPath == 0 || wcslen(pRawPath) == 0)
return CObjectPathParser::InvalidParameter;
// Check for leading / trailing ws.
// ================================
if (iswspace(pRawPath[wcslen(pRawPath)-1]) || iswspace(pRawPath[0]))
return CObjectPathParser::InvalidParameter;
// These are required for multiple calls to Parse().
// ==================================================
Empty();
Zero();
// Set default return to NULL initially until we have some output.
// ===============================================================
*pOutput = 0;
m_pOutput = new ParsedObjectPath;
if (NULL == m_pOutput)
return CObjectPathParser::OutOfMemory;
// Parse the server name (if there is one) manually
// ================================================
if ( (pRawPath[0] == '\\' && pRawPath[1] == '\\') ||
(pRawPath[0] == '/' && pRawPath[1] == '/'))
{
const WCHAR* pwcStart = pRawPath + 2;
// Find the next backslash --- it's the end of the server name
// ===========================================================
const WCHAR* pwcEnd = pwcStart;
while (*pwcEnd != L'\0' && *pwcEnd != L'\\' && *pwcEnd != L'/')
{
pwcEnd++;
}
if (*pwcEnd == L'\0')
{
// If we have already exhausted the object path string,
// a lone server name was all there was.
// ====================================================
if (m_eFlags != e_ParserAcceptAll)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::SyntaxError;
}
else // A lone server name is legal.
{
m_pOutput->m_pServer = new WCHAR[wcslen(pwcStart)+1];
if (NULL == m_pOutput->m_pServer)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::OutOfMemory;
}
wcscpy(m_pOutput->m_pServer, pwcStart);
*pOutput = m_pOutput;
m_pOutput = 0;
return CObjectPathParser::NoError;
}
}
if (pwcEnd == pwcStart)
{
// No name at all.
// ===============
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::SyntaxError;
}
m_pOutput->m_pServer = new WCHAR[pwcEnd-pwcStart+1];
if (m_pOutput->m_pServer == NULL)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::OutOfMemory;
}
wcsncpy(m_pOutput->m_pServer, pwcStart, pwcEnd-pwcStart);
m_pOutput->m_pServer[pwcEnd-pwcStart] = 0;
pRawPath = pwcEnd;
}
// Point the lexer at the source.
// ==============================
CTextLexSource src(pRawPath);
m_pLexer = new CGenLexer(OPath_LexTable, &src);
if (m_pLexer == NULL)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::OutOfMemory;
}
// Go.
// ===
int nRes = begin_parse();
if (nRes)
{
delete m_pOutput;
m_pOutput = 0;
return nRes;
}
if (m_nCurrentToken != OPATH_TOK_EOF)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::SyntaxError;
}
if (m_pOutput->m_dwNumNamespaces > 0 && m_pOutput->m_pServer == NULL)
{
if (m_eFlags != e_ParserAcceptRelativeNamespace && m_eFlags != e_ParserAcceptAll)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::SyntaxError;
}
else
{
// Local namespace --- set server to "."
// =====================================
m_pOutput->m_pServer = new WCHAR[2];
if (NULL == m_pOutput->m_pServer)
{
delete m_pOutput;
m_pOutput = 0;
return CObjectPathParser::OutOfMemory;
}
wcscpy(m_pOutput->m_pServer, L".");
}
}
// Sort the key refs lexically. If there is only
// one key, there is nothing to sort anyway.
// =============================================
if (m_pOutput->m_dwNumKeys > 1)
{
BOOL bChanges = TRUE;
while (bChanges)
{
bChanges = FALSE;
for (DWORD dwIx = 0; dwIx < m_pOutput->m_dwNumKeys - 1; dwIx++)
{
if (_wcsicmp(m_pOutput->m_paKeys[dwIx]->m_pName,
m_pOutput->m_paKeys[dwIx+1]->m_pName) > 0)
{
KeyRef *pTmp = m_pOutput->m_paKeys[dwIx];
m_pOutput->m_paKeys[dwIx] = m_pOutput->m_paKeys[dwIx + 1];
m_pOutput->m_paKeys[dwIx + 1] = pTmp;
bChanges = TRUE;
}
}
}
}
// Add in key refs.
// ================
*pOutput = m_pOutput;
m_pOutput = 0;
return CObjectPathParser::NoError;
}
BOOL CObjectPathParser::NextToken()
{
m_nCurrentToken = m_pLexer->NextToken();
if (m_nCurrentToken == OPATH_TOK_ERROR)
return FALSE;
return TRUE;
}
void CObjectPathParser::Free(ParsedObjectPath *pOutput)
{
delete pOutput;
}
//
// <Parse> ::= BACKSLASH <ns_or_server>;
// <Parse> ::= IDENT <ns_or_class>;
// <Parse> ::= COLON <objref>;
//
int CObjectPathParser::begin_parse()
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
return ns_or_server();
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
m_pInitialIdent = Macro_CloneLPWSTR(m_pLexer->GetTokenText());
if (NULL == m_pInitialIdent)
return CObjectPathParser::OutOfMemory;
if (!NextToken())
{
delete m_pInitialIdent;
m_pInitialIdent = 0;
return CObjectPathParser::SyntaxError;
}
// Copy the token and put it in a temporary holding place
// until we figure out whether it is a namespace or a class name.
// ==============================================================
return ns_or_class();
}
else if (m_nCurrentToken == OPATH_TOK_COLON)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
return objref();
}
// If here, we had a bad starter token.
// ====================================
return CObjectPathParser::SyntaxError;
}
//
// <ns_or_server> ::= BACKSLASH <dot_or_ident> BACKSLASH <ns_list> <optional_objref>;
// <ns_or_server> ::= <ns_list> <optional_objref>;
//
// <dot_or_ident> is embedded.
//
int CObjectPathParser::ns_or_server()
{
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
// Actually, server names have been take care of, so this is a failure
// ===================================================================
return CObjectPathParser::SyntaxError;
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
int nRes = ns_list();
if (nRes)
return nRes;
return optional_objref();
}
else
if (m_nCurrentToken == OPATH_TOK_EOF)
return CObjectPathParser::NoError;
return CObjectPathParser::SyntaxError;
}
//
// <optional_objref> ::= COLON <objref>;
// <optional_objref> ::= <>;
//
int CObjectPathParser::optional_objref()
{
if (m_nCurrentToken == OPATH_TOK_EOF)
return CObjectPathParser::NoError;
if (m_nCurrentToken != OPATH_TOK_COLON)
return CObjectPathParser::SyntaxError;
if (!NextToken())
return CObjectPathParser::SyntaxError;
return objref();
}
//
// <ns_or_class> ::= COLON <ident_becomes_ns> <objref>;
// <ns_or_class> ::= BACKSLASH <ident_becomes_ns> <ns_list> COLON <objref>;
// <ns_or_class> ::= BACKSLASH <ident_becomes_ns> <ns_list>;
//
int CObjectPathParser::ns_or_class()
{
int iStatus = CObjectPathParser::NoError;
if (m_nCurrentToken == OPATH_TOK_COLON)
{
iStatus = ident_becomes_ns();
if (CObjectPathParser::NoError != iStatus)
return iStatus;
if (!NextToken())
return CObjectPathParser::SyntaxError;
return objref();
}
else if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
iStatus = ident_becomes_ns();
if (CObjectPathParser::NoError != iStatus)
return iStatus;
if (!NextToken())
return CObjectPathParser::SyntaxError;
int nRes = ns_list();
if (nRes)
return nRes;
if (m_nCurrentToken == OPATH_TOK_EOF) // ns only
return CObjectPathParser::NoError;
if (m_nCurrentToken != OPATH_TOK_COLON)
return CObjectPathParser::SyntaxError;
if (!NextToken())
return CObjectPathParser::SyntaxError;
return objref();
}
// Else
// ====
iStatus = ident_becomes_class();
if (CObjectPathParser::NoError != iStatus)
return iStatus;
return objref_rest();
}
//
// <objref> ::= IDENT <objref_rest>; // IDENT is classname
//
int CObjectPathParser::objref()
{
if (m_nCurrentToken != OPATH_TOK_IDENT)
return CObjectPathParser::SyntaxError;
m_pOutput->m_pClass = Macro_CloneLPWSTR(m_pLexer->GetTokenText());
if (NULL == m_pOutput->m_pClass)
return CObjectPathParser::OutOfMemory;
// On failure here, don't free memory allocated by clone above. The ::Parse method takes care of this.
if (!NextToken())
return CObjectPathParser::SyntaxError;
return objref_rest();
}
//
// <ns_list> ::= IDENT <ns_list_rest>;
//
int CObjectPathParser::ns_list()
{
if (m_nCurrentToken == OPATH_TOK_IDENT)
{
if (!m_pOutput->AddNamespace(m_pLexer->GetTokenText()))
return CObjectPathParser::OutOfMemory;
if (!NextToken())
return CObjectPathParser::SyntaxError;
return ns_list_rest();
}
return CObjectPathParser::SyntaxError;
}
//
// <ident_becomes_ns> ::= <>; // <initial_ident> becomes a namespace
//
int CObjectPathParser::ident_becomes_ns()
{
int iStatus = CObjectPathParser::NoError;
if(!m_pOutput->AddNamespace(m_pInitialIdent))
iStatus = CObjectPathParser::OutOfMemory;
delete m_pInitialIdent;
m_pInitialIdent = 0;
return iStatus;
}
//
// <ident_becomes_class> ::= <>; // <initial_ident> becomes the class
//
int CObjectPathParser::ident_becomes_class()
{
m_pOutput->m_pClass = Macro_CloneLPWSTR(m_pInitialIdent);
delete m_pInitialIdent;
m_pInitialIdent = 0;
if (NULL == m_pOutput->m_pClass)
return CObjectPathParser::OutOfMemory;
return CObjectPathParser::NoError;
}
//
// <objref_rest> ::= EQUALS <key_const>;
// <objref_rest> ::= EQUALS *;
// <objref_rest> ::= DOT <keyref_list>;
// <objref_rest> ::= <>;
//
int CObjectPathParser::objref_rest()
{
if (m_nCurrentToken == OPATH_TOK_EQ)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
// Take care of the singleton case. This is a path of the form
// MyClass=@ and represents a singleton instance of a class with no
// keys.
if(m_nCurrentToken == OPATH_TOK_SINGLETON_SYM)
{
if(NextToken() && m_nCurrentToken != OPATH_TOK_EOF)
return CObjectPathParser::SyntaxError;
m_pOutput->m_bSingletonObj = TRUE;
return CObjectPathParser::NoError;
}
m_pTmpKeyRef = new KeyRef;
if (NULL == m_pTmpKeyRef)
return CObjectPathParser::OutOfMemory;
int nRes = key_const();
if (nRes)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return nRes;
}
if(!m_pOutput->AddKeyRef(m_pTmpKeyRef))
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return CObjectPathParser::OutOfMemory;
}
m_pTmpKeyRef = 0;
}
else if (m_nCurrentToken == OPATH_TOK_DOT)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
return keyref_list();
}
return CObjectPathParser::NoError;
}
//
// <ns_list_rest> ::= BACKSLASH <ns_list>;
// <ns_list_rest> ::= <>;
//
int CObjectPathParser::ns_list_rest()
{
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
return ns_list();
}
return CObjectPathParser::NoError;
}
//
// <key_const> ::= STRING_CONST;
// <key_const> ::= INTEGRAL_CONST;
// <key_const> ::= REAL_CONST;
// <key_const> ::= IDENT; // Where IDENT is "OBJECT" for singleton classes
//
int CObjectPathParser::key_const()
{
// If here, we have a key constant.
// We may or may not have the property name
// associated with it.
// ========================================
if (m_nCurrentToken == OPATH_TOK_QSTRING)
{
V_VT(&m_pTmpKeyRef->m_vValue) = VT_BSTR;
wchar_t *pTokenText = m_pLexer->GetTokenText();
if (NULL == pTokenText)
return CObjectPathParser::SyntaxError;
BSTR bstr = SysAllocString(pTokenText);
if (NULL == bstr)
return CObjectPathParser::OutOfMemory;
V_BSTR(&m_pTmpKeyRef->m_vValue) = bstr;
// Keeping the original code commented out for now. Replacement is complicated
// because several failures could have occured and those would be obscured in the
// previous version.
// V_BSTR(&m_pTmpKeyRef->m_vValue) = SysAllocString(m_pLexer->GetTokenText());
// if (NULL == pKeyRef->m_vValue)
// return CObjectPathParser::OutOfMemory;
}
else if (m_nCurrentToken == OPATH_TOK_INT)
{
V_VT(&m_pTmpKeyRef->m_vValue) = VT_I4;
char buf[32];
if(m_pLexer->GetTokenText() == NULL || wcslen(m_pLexer->GetTokenText()) > 31)
return CObjectPathParser::SyntaxError;
sprintf(buf, "%S", m_pLexer->GetTokenText());
V_I4(&m_pTmpKeyRef->m_vValue) = atol(buf);
}
else if (m_nCurrentToken == OPATH_TOK_HEXINT)
{
V_VT(&m_pTmpKeyRef->m_vValue) = VT_I4;
char buf[32];
if(m_pLexer->GetTokenText() == NULL || wcslen(m_pLexer->GetTokenText()) > 31)
return CObjectPathParser::SyntaxError;
sprintf(buf, "%S", m_pLexer->GetTokenText());
long l;
sscanf(buf, "%x", &l);
V_I4(&m_pTmpKeyRef->m_vValue) = l;
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
if (_wcsicmp(m_pLexer->GetTokenText(), L"TRUE") == 0)
{
V_VT(&m_pTmpKeyRef->m_vValue) = VT_I4;
V_I4(&m_pTmpKeyRef->m_vValue) = 1;
}
else if (_wcsicmp(m_pLexer->GetTokenText(), L"FALSE") == 0)
{
V_VT(&m_pTmpKeyRef->m_vValue) = VT_I4;
V_I4(&m_pTmpKeyRef->m_vValue) = 0;
}
else
return CObjectPathParser::SyntaxError;
}
else return CObjectPathParser::SyntaxError;
if (!NextToken())
return CObjectPathParser::SyntaxError;
return CObjectPathParser::NoError;
}
//
// <keyref_list> ::= <keyref> <keyref_term>;
//
int CObjectPathParser::keyref_list()
{
int nRes = keyref();
if (nRes)
return nRes;
return keyref_term();
}
//
// <keyref> ::= <propname> EQUALS <key_const>;
//
int CObjectPathParser::keyref()
{
m_pTmpKeyRef = new KeyRef;
if (m_pTmpKeyRef == NULL)
{
return CObjectPathParser::OutOfMemory;
}
int nRes = propname();
if (nRes)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return nRes;
}
if (m_nCurrentToken != OPATH_TOK_EQ)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return CObjectPathParser::SyntaxError;
}
if (!NextToken())
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return CObjectPathParser::SyntaxError;
}
nRes = key_const();
if (nRes)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return nRes;
}
if (!m_pOutput->AddKeyRef(m_pTmpKeyRef))
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return CObjectPathParser::OutOfMemory;
}
m_pTmpKeyRef = 0;
return CObjectPathParser::NoError;
}
//
// <keyref_term> ::= COMMA <keyref_list>; // Used for compound keys
// <keyref_term> ::= <>;
//
int CObjectPathParser::keyref_term()
{
if (m_nCurrentToken == OPATH_TOK_COMMA)
{
if (!NextToken())
return CObjectPathParser::SyntaxError;
return keyref_list();
}
return CObjectPathParser::NoError;
}
//
// <propname> ::= IDENT;
//
int CObjectPathParser::propname()
{
if (m_nCurrentToken != OPATH_TOK_IDENT)
return CObjectPathParser::SyntaxError;
m_pTmpKeyRef->m_pName = Macro_CloneLPWSTR(m_pLexer->GetTokenText());
if (NULL == m_pTmpKeyRef->m_pName)
return CObjectPathParser::OutOfMemory;
if (!NextToken())
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return CObjectPathParser::SyntaxError;
}
return CObjectPathParser::NoError;
}
//***************************************************************************
//
// ParsedObjectPath::GetKeyString
//
// Returns the db-engine compatible key string for the object.
// The format will likely change after the Alpha PDK Release.
//
// Return value:
// NULL on error or for pure classes. Otherwise returns a pointer to
// a newly allocated string which must be deallocated with operator
// delete.
//
//***************************************************************************
LPWSTR ParsedObjectPath::GetKeyString()
{
if (m_dwNumKeys == 0 && !m_bSingletonObj)
{
if (m_pClass == 0 || wcslen(m_pClass) == 0)
return 0;
LPWSTR pTmp = new wchar_t[wcslen(m_pClass) + 1];
if (pTmp)
wcscpy(pTmp, m_pClass);
return pTmp;
}
// Allocate enough space
// =====================
int nSpace = 10;
DWORD dwIx;
for (dwIx = 0; dwIx < m_dwNumKeys; dwIx++)
{
KeyRef* pKey = m_paKeys[dwIx];
nSpace += 2; // for the |
if(V_VT(&pKey->m_vValue) == VT_BSTR)
{
nSpace += wcslen(V_BSTR(&pKey->m_vValue))*2 + 10;
}
else if(V_VT(&pKey->m_vValue) == VT_I4)
{
nSpace += 30;
}
}
if(m_bSingletonObj)
nSpace +=20;
LPWSTR pRetVal = new wchar_t[nSpace];
if (NULL == pRetVal)
return NULL;
wchar_t Tmp[32];
long nVal;
*pRetVal = 0;
BOOL bFirst = TRUE;
// The key are already sorted lexically.
// =====================================
WCHAR wszSeparator[2];
wszSeparator[0] = 0xFFFF;
wszSeparator[1] = 0;
for (DWORD i = 0; i < m_dwNumKeys; i++)
{
if (!bFirst)
wcscat(pRetVal, wszSeparator);
bFirst = FALSE;
KeyRef *pKeyRef = m_paKeys[i];
VARIANT *pv = &pKeyRef->m_vValue;
int nType = V_VT(pv);
switch (nType)
{
case VT_LPWSTR:
case VT_BSTR:
wcscat(pRetVal, V_BSTR(pv));
break;
case VT_I4:
nVal = V_I4(pv);
swprintf(Tmp, L"%d", nVal);
wcscat(pRetVal, Tmp);
break;
case VT_I2:
nVal = V_I2(pv);
swprintf(Tmp, L"%d", nVal);
wcscat(pRetVal, Tmp);
break;
case VT_UI1:
nVal = V_UI1(pv);
swprintf(Tmp, L"%d", nVal);
wcscat(pRetVal, Tmp);
break;
case VT_BOOL:
nVal = V_BOOL(pv);
swprintf(Tmp, L"%d", (nVal?1:0));
wcscat(pRetVal, Tmp);
break;
default:
wcscat(pRetVal, L"NULL");
}
}
if (wcslen(pRetVal) == 0)
{
if(m_bSingletonObj)
{
wcscpy(pRetVal, L"@");
}
}
return pRetVal; // This may not be NULL
}
LPWSTR ParsedObjectPath::GetNamespacePart()
{
if (m_dwNumNamespaces == 0)
return NULL;
// Compute necessary space
// =======================
int nSpace = 0;
for(DWORD i = 0; i < m_dwNumNamespaces; i++)
nSpace += 1 + wcslen(m_paNamespaces[i]);
nSpace--;
// Allocate buffer
// ===============
LPWSTR wszOut = new wchar_t[nSpace + 1];
if (wszOut == NULL)
return NULL;
*wszOut = 0;
// Output
// ======
for(i = 0; i < m_dwNumNamespaces; i++)
{
if(i != 0) wcscat(wszOut, L"\\");
wcscat(wszOut, m_paNamespaces[i]);
}
return wszOut;
}
LPWSTR ParsedObjectPath::GetParentNamespacePart()
{
if(m_dwNumNamespaces < 2)
return NULL;
// Compute necessary space
// =======================
int nSpace = 0;
for(DWORD i = 0; i < m_dwNumNamespaces - 1; i++)
nSpace += 1 + wcslen(m_paNamespaces[i]);
nSpace--;
// Allocate buffer
// ===============
LPWSTR wszOut = new wchar_t[nSpace + 1];
if (NULL == wszOut)
return NULL;
*wszOut = 0;
// Output
// ======
for(i = 0; i < m_dwNumNamespaces - 1; i++)
{
if(i != 0) wcscat(wszOut, L"\\");
wcscat(wszOut, m_paNamespaces[i]);
}
return wszOut;
}
BOOL ParsedObjectPath::IncreaseNumAllocKeys()
{
if(0 == m_dwAllocKeys || m_dwNumKeys == m_dwAllocKeys)
{
// Here if array is full or allocation failed previously
DWORD dwNewAllocKeys = 0;
if (0 == m_dwAllocKeys)
{
dwNewAllocKeys = m_scdwAllocKeysChunkSize;
}
else
{
dwNewAllocKeys = m_dwAllocKeys * 2;
}
KeyRef** paNewKeys = new KeyRef*[dwNewAllocKeys];
if (paNewKeys == NULL)
{
return FALSE;
}
unsigned int i = 0;
// Initialize the new array to NULLs
for (i = 0; i < dwNewAllocKeys; i++)
paNewKeys[i] = 0;
if (NULL != m_paKeys)
{
// Here only if we previously had an allocation success
memcpy(paNewKeys, m_paKeys, sizeof(KeyRef*) * m_dwNumKeys);
delete [] m_paKeys;
}
m_paKeys = paNewKeys;
m_dwAllocKeys = dwNewAllocKeys;
}
return TRUE;
}
////////////////////////////////////////////////////////
//
// Test object path parser by parsing all objects
// in the input file (one object path per line).
//
////////////////////////////////////////////////////////
#ifdef TEST
void xmain(int argc, wchar_t * argv[])
{
// printf("Object Path Test\n");
// if (argc < 2 || strchr(argv[1], '?') != NULL)
// {
// printf("Usage: objpath input-file\n");
// return;
// }
int nLine = 1;
char buf[2048];
printf("Your argument was: %s\n", argv[1]);
return;
// FILE *f = fopen(argv[1], "rt");
FILE *f = fopen("junk.txt", "rt");
if (f == NULL)
{
printf("Usage: objpath input-file\nError: cannot open file %s!\n", argv[1]);
return;
}
while (fgets(buf, 2048, f) != NULL)
{
// Get rid of newline and trailing spaces.
// =======================================
char* ptr = strchr(buf, '\n');
if (ptr != NULL)
{
*ptr = ' ';
while (ptr >= buf && *ptr == ' ')
{
*ptr = '\0';
ptr--;
}
}
// Get rid of leading spaces.
// ==========================
ptr = buf;
while (*ptr == ' ')
{
ptr++;
}
// Convert to wide char and parse. Ignore blank lines.
// ====================================================
if (*ptr != '\0')
{
wchar_t buf2[2048];
MultiByteToWideChar(CP_ACP, 0, ptr, -1, buf2, 2048);
printf("----Object path----\n");
printf("%S\n", buf2);
ParsedObjectPath* pOutput = 0;
CObjectPathParser p(e_ParserAcceptAll);
int nStatus = p.Parse(buf2, &pOutput);
if (nStatus != 0)
{
printf("ERROR: return code is %d\n", nStatus);
continue;
}
printf("No errors.\n");
printf("------Output------\n");
LPWSTR pKey = pOutput->GetKeyString();
printf("Key String = <%S>\n", pKey);
delete pKey;
printf("Server = %S\n", pOutput->m_pServer);
printf("Namespace Part = %S\n", pOutput->GetNamespacePart());
printf("Parent Part = %S\n", pOutput->GetParentNamespacePart());
for (DWORD dwIx = 0; dwIx < pOutput->m_dwNumNamespaces; dwIx++)
{
printf("Namespace = <%S>\n", pOutput->m_paNamespaces[dwIx]);
}
printf("Class = <%S>\n", pOutput->m_pClass);
// If here, the key ref is complete.
// =================================
for (dwIx = 0; dwIx < pOutput->m_dwNumKeys; dwIx++)
{
KeyRef *pTmp = pOutput->m_paKeys[dwIx];
printf("*** KeyRef contents:\n");
printf(" Name = %S Value=", pTmp->m_pName);
switch (V_VT(&pTmp->m_vValue))
{
case VT_I4: printf("%d", V_I4(&pTmp->m_vValue)); break;
case VT_R8: printf("%f", V_R8(&pTmp->m_vValue)); break;
case VT_BSTR: printf("<%S>", V_BSTR(&pTmp->m_vValue)); break;
default:
printf("BAD KEY REF\n");
}
printf("\n");
}
p.Free(pOutput);
}
}
}
int __cdecl wmain(int argc, wchar_t * argv[])
{
xmain(argc, argv);
return 0;
}
#endif