Source code of Windows XP (NT5)
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/*++
// Copyright (c) 1998-2001 Microsoft Corporation, All Rights Reserved
Module Name:
ActualParse.CPP
Abstract:
Implements the object path parser engine
History:
a-davj 11-feb-00 Created.
--*/
#include "precomp.h"
#include <genlex.h>
#include "opathlex2.h"
#include "PathParse.h"
#include "ActualParse.h"
#include "commain.h"
//#include "resource.h"
#include "wbemcli.h"
#include <stdio.h>
#include "helpers.h"
//***************************************************************************
//
// CActualPathParser
//
//***************************************************************************
LPWSTR CActualPathParser::GetRelativePath(LPWSTR wszFullPath)
{
// We need the last colon, if any
LPWSTR wszTemp = wcschr(wszFullPath, L':');
while (wszTemp != NULL)
{
LPWSTR wszSave = wszTemp;
wszTemp++;
wszTemp = wcschr(wszTemp, L':');
if (!wszTemp)
{
wszTemp = wszSave;
break;
}
}
if (wszTemp)
return wszTemp + 1;
else
return NULL;
}
void CActualPathParser::Zero()
{
m_nCurrentToken = 0;
m_pLexer = 0;
m_pInitialIdent = 0;
m_pOutput = 0;
m_pTmpKeyRef = 0;
}
CActualPathParser::CActualPathParser(DWORD eFlags)
: m_eFlags(eFlags)
{
Zero();
}
void CActualPathParser::Empty()
{
delete m_pLexer;
delete m_pInitialIdent;
delete m_pTmpKeyRef;
// m_pOutput is intentionally left alone,
// since all code paths delete this already on error, or
// else the user acquired the pointer.
}
CActualPathParser::~CActualPathParser()
{
Empty();
}
int CActualPathParser::Parse(
LPCWSTR pRawPath,
CDefPathParser & Output
)
{
DWORD dwTest = m_eFlags & ~WBEMPATH_TREAT_SINGLE_IDENT_AS_NS;
if(dwTest != WBEMPATH_CREATE_ACCEPT_RELATIVE &&
dwTest != WBEMPATH_CREATE_ACCEPT_ABSOLUTE &&
dwTest != WBEMPATH_CREATE_ACCEPT_ALL)
return CActualPathParser::InvalidParameter;
if (pRawPath == 0 || wcslen(pRawPath) == 0)
return CActualPathParser::InvalidParameter;
// Check for leading / trailing ws.
// ================================
if (iswspace(pRawPath[wcslen(pRawPath)-1]) || iswspace(pRawPath[0]))
return InvalidParameter;
// These are required for multiple calls to Parse().
// ==================================================
Empty();
Zero();
m_pOutput = &Output;
// 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
// Since the next slash can be either, search for both and take
// the first one. If the first character is a '[', then then
// end is indicated by a ']'
// ============================================================
WCHAR* pwcEnd = NULL;
if(*pwcStart == L'[')
{
// look for the ']'
WCHAR * pCloseBrace = wcschr(pwcStart, L']');
if(pCloseBrace == NULL)
return SyntaxError;
pwcEnd = pCloseBrace+1;
}
else
{
WCHAR* pwcNextBack = wcschr(pwcStart, L'\\');
WCHAR* pwcNextForward = wcschr(pwcStart, L'/');
pwcEnd = pwcNextBack;
if(pwcEnd == NULL)
pwcEnd = pwcNextForward;
else if(pwcNextForward && (pwcNextForward < pwcNextBack))
pwcEnd = pwcNextForward;
}
if (pwcEnd == NULL)
{
// If we have already exhausted the object path string,
// a lone server name was all there was.
// ====================================================
if ((m_eFlags & WBEMPATH_CREATE_ACCEPT_ALL) == 0)
{
return SyntaxError;
}
else // A lone server name is legal.
{
m_pOutput->SetServer(pwcStart);
return NoError;
}
}
if(pwcEnd == pwcStart)
{
// No name at all.
// ===============
return SyntaxError;
}
WCHAR * wTemp = new WCHAR[pwcEnd-pwcStart+1];
if(wTemp == NULL)
return NoMemory;
wcsncpy(wTemp, pwcStart, pwcEnd-pwcStart);
wTemp[pwcEnd-pwcStart] = 0;
m_pOutput->SetServer(wTemp, false, true);
pRawPath = pwcEnd;
}
// Point the lexer at the source.
// ==============================
CTextLexSource src((LPWSTR)pRawPath);
{
AutoClear ac(this);
m_pLexer = new CGenLexer(OPath_LexTable2, &src);
if(m_pLexer == NULL)
return NoMemory;
Output.m_pGenLex = m_pLexer; // TEST CODE
// Go.
// ===
int nRes = begin_parse();
if (nRes)
{
return nRes;
}
if (m_nCurrentToken != OPATH_TOK_EOF)
{
return SyntaxError;
}
if (m_pOutput->GetNumComponents() > 0 && !m_pOutput->HasServer())
{
if ( ! ( m_eFlags & WBEMPATH_CREATE_ACCEPT_RELATIVE ) && ! ( m_eFlags & WBEMPATH_CREATE_ACCEPT_ALL ) )
{
return SyntaxError;
}
else
{
// Local namespace --- set server to "."
// =====================================
m_pOutput->SetServer(L".", true, false);
}
}
}
Output.SortKeys();
// Add in key refs.
// ================
return NoError;
}
BOOL CActualPathParser::NextToken()
{
m_nCurrentToken = m_pLexer->NextToken();
if (m_nCurrentToken == OPATH_TOK_ERROR)
return FALSE;
return TRUE;
}
//
// <Parse> ::= BACKSLASH <ns_or_server>;
// <Parse> ::= IDENT <ns_or_class>;
// <Parse> ::= COLON <ns_or_class>;
//
int CActualPathParser::begin_parse()
{
if (!NextToken())
return SyntaxError;
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
if (!NextToken())
return SyntaxError;
return ns_or_server();
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
m_pInitialIdent = Macro_CloneLPWSTR(m_pLexer->GetTokenText());
if(m_pInitialIdent == NULL)
return NoMemory;
if (!NextToken())
return 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)
{
// A colon may indicate a namespace now...
if (!NextToken())
return SyntaxError;
return ns_or_class();
}
// If here, we had a bad starter token.
// ====================================
return SyntaxError;
}
//
// <ns_or_server> ::= IDENT <ns_list>;
//
int CActualPathParser::ns_or_server()
{
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
// Actually, server names have been take care of, so this is a failure
// ===================================================================
return SyntaxError;
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
return ns_list();
}
else
if (m_nCurrentToken == OPATH_TOK_EOF)
return NoError;
return SyntaxError;
}
// <ns_or_class> ::= COLON <ident_becomes_ns> <objref> <optional_scope_class_list>;
// <ns_or_class> ::= BACKSLASH <ident_becomes_ns> <ns_list>;
// <ns_or_class> ::= <ident_becomes_ns> <objref_rest>;
// <ns_or_class> ::= <ident_becomes_class> <objref_rest>;
int CActualPathParser::ns_or_class()
{
if (m_nCurrentToken == OPATH_TOK_COLON)
{
ident_becomes_ns();
if (!NextToken())
return SyntaxError;
int nRes = objref();
if (nRes)
return nRes;
if ((m_nCurrentToken != OPATH_TOK_EOF))
return optional_scope_class_list();
return NoError;
}
else if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
ident_becomes_ns();
if (!NextToken())
return SyntaxError;
return ns_list();
}
else if ((m_nCurrentToken == OPATH_TOK_EOF) &&
(m_eFlags & WBEMPATH_TREAT_SINGLE_IDENT_AS_NS))
{
return ident_becomes_ns();
}
// Else
// ====
ident_becomes_class();
if(objref_rest())
return SyntaxError;
else
return optional_scope_class_list();
}
// <optional_scope_class_list> ::= COLON <objref> <optional_scope_class_list>
// <optional_scope_class_list> ::= <>
int CActualPathParser::optional_scope_class_list()
{
if (m_nCurrentToken == OPATH_TOK_EOF)
return NoError;
else if (m_nCurrentToken == OPATH_TOK_COLON)
{
if (!NextToken())
return SyntaxError;
if (objref() == NoError)
return optional_scope_class_list();
return SyntaxError;
}
return NoError;
}
//
// <objref> ::= IDENT <objref_rest>; // IDENT is classname
//
int CActualPathParser::objref()
{
if (m_nCurrentToken != OPATH_TOK_IDENT)
return SyntaxError;
m_pOutput->AddClass(m_pLexer->GetTokenText());
if (!NextToken())
return SyntaxError;
return objref_rest();
}
//
// <ns_list> ::= IDENT <ns_list_rest>;
//
int CActualPathParser::ns_list()
{
if (m_nCurrentToken == OPATH_TOK_IDENT)
{
m_pOutput->AddNamespace(m_pLexer->GetTokenText());
if (!NextToken())
return SyntaxError;
return ns_list_rest();
}
return SyntaxError;
}
//
// <ident_becomes_ns> ::= <>; // <initial_ident> becomes a namespace
//
int CActualPathParser::ident_becomes_ns()
{
m_pOutput->AddNamespace(m_pInitialIdent);
delete m_pInitialIdent;
m_pInitialIdent = 0;
return NoError;
}
//
// <ident_becomes_class> ::= <>; // <initial_ident> becomes the class
//
int CActualPathParser::ident_becomes_class()
{
m_pOutput->AddClass(m_pInitialIdent);
delete m_pInitialIdent;
m_pInitialIdent = 0;
return NoError;
}
//
// <objref_rest> ::= EQUALS <key_const>;
// <objref_rest> ::= EQUALS @;
// <objref_rest> ::= DOT <keyref_list>;
// <objref_rest> ::= <>;
//
int CActualPathParser::objref_rest()
{
if (m_nCurrentToken == OPATH_TOK_EQ)
{
if (!NextToken())
return 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)
{
NextToken();
m_pOutput->SetSingletonObj();
return NoError;
}
m_pTmpKeyRef = new CKeyRef;
if(m_pTmpKeyRef == NULL)
return NoMemory;
int nRes = key_const();
if (nRes)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return nRes;
}
m_pOutput->AddKeyRef(m_pTmpKeyRef);
m_pTmpKeyRef = 0;
}
else if (m_nCurrentToken == OPATH_TOK_DOT)
{
if (!NextToken())
return SyntaxError;
return keyref_list();
}
return NoError;
}
//
// <ns_list_rest> ::= BACKSLASH <ns_list>;
// <ns_list_rest> ::= COLON <objref> <optional_scope_class_list>;
// <ns_list_rest> ::= <>;
int CActualPathParser::ns_list_rest()
{
if (m_nCurrentToken == OPATH_TOK_BACKSLASH)
{
if (!NextToken())
return SyntaxError;
return ns_list();
}
else if (m_nCurrentToken == OPATH_TOK_COLON)
{
if (!NextToken())
return SyntaxError;
if (objref() == NoError)
return optional_scope_class_list();
return SyntaxError;
}
return NoError;
}
//
// <key_const> ::= STRING_CONST;
// <key_const> ::= INTEGRAL_CONST;
// <key_const> ::= REAL_CONST;
// <key_const> ::= IDENT; // Where IDENT is "OBJECT" for singleton classes
//
int CActualPathParser::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)
{
int iNumByte = 2*(wcslen(m_pLexer->GetTokenText()) +1);
m_pTmpKeyRef->SetData(CIM_STRING, iNumByte, m_pLexer->GetTokenText());
}
else if (m_nCurrentToken == OPATH_TOK_REFERENCE)
{
int iNumByte = 2*(wcslen(m_pLexer->GetTokenText()) +1);
m_pTmpKeyRef->SetData(CIM_REFERENCE, iNumByte, m_pLexer->GetTokenText());
}
else if (m_nCurrentToken == OPATH_TOK_INT)
{
if(*(m_pLexer->GetTokenText()) == L'-')
{
__int64 llVal = _wtoi64(m_pLexer->GetTokenText());
if(llVal > 2147483647 || llVal < -(__int64)2147483648)
m_pTmpKeyRef->SetData(CIM_SINT64, 8, &llVal);
else
m_pTmpKeyRef->SetData(CIM_SINT32, 4, &llVal);
}
else
{
unsigned __int64 ullVal;
if(0 == swscanf(m_pLexer->GetTokenText(), L"%I64u", &ullVal))
return SyntaxError;
if(ullVal < 2147483648)
m_pTmpKeyRef->SetData(CIM_SINT32, 4, &ullVal);
else if(ullVal > 0xffffffff)
m_pTmpKeyRef->SetData(CIM_UINT64, 8, &ullVal);
else
m_pTmpKeyRef->SetData(CIM_UINT32, 4, &ullVal);
}
}
else if (m_nCurrentToken == OPATH_TOK_HEXINT)
{
unsigned __int64 ullVal;
if(0 ==swscanf(m_pLexer->GetTokenText(),L"%I64x", &ullVal))
return SyntaxError;
m_pTmpKeyRef->SetData(CIM_UINT64, 8, &ullVal);
}
else if (m_nCurrentToken == OPATH_TOK_IDENT)
{
if (_wcsicmp(m_pLexer->GetTokenText(), L"TRUE") == 0)
{
long lVal = 1;
m_pTmpKeyRef->SetData(CIM_BOOLEAN, 4, &lVal);
}
else if (_wcsicmp(m_pLexer->GetTokenText(), L"FALSE") == 0)
{
long lVal = 0;
m_pTmpKeyRef->SetData(CIM_BOOLEAN, 4, &lVal);
}
else
return SyntaxError;
}
else return SyntaxError;
if (!NextToken())
return SyntaxError;
return NoError;
}
//
// <keyref_list> ::= <keyref> <keyref_term>;
//
int CActualPathParser::keyref_list()
{
int nRes = keyref();
if (nRes)
return nRes;
return keyref_term();
}
//
// <keyref> ::= <propname> EQUALS <key_const>;
//
int CActualPathParser::keyref()
{
m_pTmpKeyRef = new CKeyRef;
if(m_pTmpKeyRef == NULL)
return NoMemory;
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 SyntaxError;
}
if (!NextToken())
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return SyntaxError;
}
nRes = key_const();
if (nRes)
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return nRes;
}
m_pOutput->AddKeyRef(m_pTmpKeyRef);
m_pTmpKeyRef = 0;
return NoError;
}
//
// <keyref_term> ::= COMMA <keyref_list>; // Used for compound keys
// <keyref_term> ::= <>;
//
int CActualPathParser::keyref_term()
{
if (m_nCurrentToken == OPATH_TOK_COMMA)
{
if (!NextToken())
return SyntaxError;
return keyref_list();
}
return NoError;
}
//
// <propname> ::= IDENT;
//
int CActualPathParser::propname()
{
if (m_nCurrentToken != OPATH_TOK_IDENT)
return SyntaxError;
m_pTmpKeyRef->m_pName = Macro_CloneLPWSTR(m_pLexer->GetTokenText());
if (!m_pTmpKeyRef->m_pName)
return NoMemory;
if (!NextToken())
{
delete m_pTmpKeyRef;
m_pTmpKeyRef = 0;
return SyntaxError;
}
return NoError;
}