windows-nt/Source/XPSP1/NT/net/rras/ras/ppp/engine/init.c

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2020-09-26 03:20:57 -05:00
/********************************************************************/
/** Copyright(c) 1989 Microsoft Corporation. **/
/********************************************************************/
//***
//
// Filename: init.c
//
// Description: This module contains all the code to initialize the PPP
// engine.
//
// History:
// Nov 11,1993. NarenG Created original version.
//
#include <nt.h>
#include <ntrtl.h>
#include <nturtl.h> // needed for winbase.h
#include <windows.h> // Win32 base API's
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <wchar.h>
#include <raserror.h>
#include <rasman.h>
#include <rtutils.h>
#include <mprlog.h>
#include <lmcons.h>
#include <rasppp.h>
#include <pppcp.h>
#include <lcp.h>
#define _ALLOCATE_GLOBALS_
#include <ppp.h>
#include <timer.h>
#include <util.h>
#include <worker.h>
#include <init.h>
#include <rasauth.h>
#include <bap.h>
#include <raseapif.h>
#define __NOT_INCLUDE_OpenRAS_IASProfileDlg__
#include <dialinusr.h>
#define ALLOC_BLTINCPS_GLOBALS
#include <bltincps.h>
// AFP Server Service registry parameter structure
//
typedef struct _PPP_REGISTRY_PARAMS {
LPSTR pszValueName;
DWORD * pValue;
DWORD Max;
DWORD dwDefValue;
} PPP_REGISTRY_PARAMS, *PPPP_REGISTRY_PARAMS;
PPP_REGISTRY_PARAMS PppRegParams[] =
{
RAS_VALUENAME_MAXTERMINATE,
&(PppConfigInfo.MaxTerminate),
255,
PPP_DEF_MAXTERMINATE,
RAS_VALUENAME_MAXCONFIGURE,
&(PppConfigInfo.MaxConfigure),
255,
PPP_DEF_MAXCONFIGURE,
RAS_VALUENAME_MAXFAILURE,
&(PppConfigInfo.MaxFailure),
255,
PPP_DEF_MAXFAILURE,
RAS_VALUENAME_MAXREJECT,
&(PppConfigInfo.MaxReject),
255,
PPP_DEF_MAXREJECT,
RAS_VALUENAME_RESTARTTIMER,
&(PppConfigInfo.DefRestartTimer),
0xFFFFFFFF,
PPP_DEF_RESTARTTIMER,
RAS_VALUENAME_NEGOTIATETIME,
&(PppConfigInfo.NegotiateTime),
0xFFFFFFFF,
PPP_DEF_NEGOTIATETIME,
RAS_VALUENAME_CALLBACKDELAY,
&(PppConfigInfo.dwCallbackDelay),
255,
PPP_DEF_CALLBACKDELAY,
RAS_VALUENAME_PORTLIMIT,
&(PppConfigInfo.dwDefaultPortLimit),
0xFFFFFFFF,
PPP_DEF_PORTLIMIT,
RAS_VALUENAME_SESSIONTIMEOUT,
&(PppConfigInfo.dwDefaultSessionTimeout),
0xFFFFFFFF,
PPP_DEF_SESSIONTIMEOUT,
RAS_VALUENAME_IDLETIMEOUT,
&(PppConfigInfo.dwDefaulIdleTimeout),
0xFFFFFFFF,
PPP_DEF_IDLETIMEOUT,
RAS_VALUENAME_BAPTHRESHOLD,
&(PppConfigInfo.dwHangupExtraPercent),
100,
RAS_DEF_BAPLINEDNLIMIT,
RAS_VALUENAME_BAPTIME,
&(PppConfigInfo.dwHangUpExtraSampleSeconds),
0xFFFFFFFF,
RAS_DEF_BAPLINEDNTIME,
RAS_VALUENAME_BAPLISTENTIME,
&(PppConfigInfo.dwBapListenTimeoutSeconds),
0xFFFFFFFF,
PPP_DEF_BAPLISTENTIME,
RAS_VALUENAME_UNKNOWNPACKETTRACESIZE,
&(PppConfigInfo.dwUnknownPacketTraceSize),
0xFFFFFFFF,
PPP_DEF_UNKNOWNPACKETTRACESIZE,
RAS_ECHO_REQUEST_INTERVAL,
&(PppConfigInfo.dwLCPEchoTimeInterval),
0xFFFFFFFF,
PPP_DEF_ECHO_REQUEST_INTERVAL, //Default of 60 seconds
RAS_ECHO_REQUEST_IDLE,
&(PppConfigInfo.dwIdleBeforeEcho),
0xFFFFFFFF,
PPP_DEF_ECHO_REQUEST_IDLE, //Default of 300 seconds
RAS_ECHO_NUM_MISSED_ECHOS,
&(PppConfigInfo.dwNumMissedEchosBeforeDisconnect),
0xFFFFFFFF,
PPP_DEF_ECHO_NUM_MISSED_ECHOS, //Default of 3 tries
RAS_DONTNEGOTIATE_MULTILINKONSINGLELINK,
&(PppConfigInfo.dwDontNegotiateMultiLinkOnSingleLink),
0xFFFFFFFF,
0,
NULL, NULL, 0, 0
};
static DLL_ENTRY_POINTS * pCpDlls = (DLL_ENTRY_POINTS*)NULL;
HANDLE HInstDLL;
//**
//
// Call: LoadProtocolDlls
//
// Returns: NO_ERROR - Success
// non-zero code - Failure
//
// Description: This procedure enumerates all the Subkeys under the PPP key
// and loads each AP or CP and fills up the DLL_ENTRY_POINTS
// structure with the required entry points. It also will return
// the total number of protocols in all the Dlls. Note that each
// DLL could have up to PPPCP_MAXCPSPERDLL protocols.
//
DWORD
LoadProtocolDlls(
IN DLL_ENTRY_POINTS * pCpDlls,
IN DWORD cCpDlls,
IN HKEY hKeyProtocols,
OUT DWORD * pcTotalNumProtocols
)
{
HKEY hKeyCp = (HKEY)NULL;
LPSTR pCpDllPath = (LPSTR)NULL;
LPSTR pCpDllExpandedPath = (LPSTR)NULL;
DWORD dwKeyIndex;
DWORD dwRetCode;
CHAR chSubKeyName[100];
DWORD cbSubKeyName;
DWORD dwNumSubKeys;
DWORD dwMaxSubKeySize;
DWORD dwNumValues;
DWORD cbMaxValNameLen;
DWORD cbMaxValueDataSize;
DWORD dwSecDescLen;
DWORD ProtocolIds[PPPCP_MAXCPSPERDLL];
DWORD dwNumProtocolIds;
FARPROC pRasCpEnumProtocolIds;
FARPROC pRasCpGetInfo;
DWORD cbSize;
DWORD dwType;
HINSTANCE hInstance;
//
// Read the registry to find out the various control protocols to load.
//
for ( dwKeyIndex = 0; dwKeyIndex < cCpDlls; dwKeyIndex++ )
{
cbSubKeyName = sizeof( chSubKeyName );
dwRetCode = RegEnumKeyEx(
hKeyProtocols,
dwKeyIndex,
chSubKeyName,
&cbSubKeyName,
NULL,
NULL,
NULL,
NULL
);
if ( ( dwRetCode != NO_ERROR ) &&
( dwRetCode != ERROR_MORE_DATA ) &&
( dwRetCode != ERROR_NO_MORE_ITEMS ) )
{
PppLogErrorString(ROUTERLOG_CANT_ENUM_REGKEYVALUES,0,
NULL,dwRetCode,0);
break;
}
dwRetCode = RegOpenKeyEx(
hKeyProtocols,
chSubKeyName,
0,
KEY_QUERY_VALUE,
&hKeyCp );
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(ROUTERLOG_CANT_OPEN_PPP_REGKEY,0,NULL,
dwRetCode,0);
break;
}
//
// Find out the size of the path value.
//
dwRetCode = RegQueryInfoKey(
hKeyCp,
NULL,
NULL,
NULL,
&dwNumSubKeys,
&dwMaxSubKeySize,
NULL,
&dwNumValues,
&cbMaxValNameLen,
&cbMaxValueDataSize,
NULL,
NULL
);
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(ROUTERLOG_CANT_OPEN_PPP_REGKEY,0,NULL,
dwRetCode,0);
break;
}
//
// Allocate space for path and add one for NULL terminator
//
pCpDllPath = (LPBYTE)LOCAL_ALLOC( LPTR, ++cbMaxValueDataSize );
if ( pCpDllPath == (LPBYTE)NULL )
{
dwRetCode = GetLastError();
PppLogError( ROUTERLOG_NOT_ENOUGH_MEMORY, 0, NULL, dwRetCode);
break;
}
//
// Read in the path
//
dwRetCode = RegQueryValueEx(
hKeyCp,
RAS_VALUENAME_PATH,
NULL,
&dwType,
pCpDllPath,
&cbMaxValueDataSize
);
if ( dwRetCode != NO_ERROR )
{
PppLogError(ROUTERLOG_CANT_GET_REGKEYVALUES, 0, NULL, dwRetCode );
break;
}
if ( ( dwType != REG_EXPAND_SZ ) && ( dwType != REG_SZ ) )
{
dwRetCode = ERROR_REGISTRY_CORRUPT;
PppLogError( ROUTERLOG_CANT_GET_REGKEYVALUES, 0, NULL, dwRetCode );
break;
}
//
// Replace the %SystemRoot% with the actual path.
//
cbSize = ExpandEnvironmentStrings( pCpDllPath, NULL, 0 );
if ( cbSize == 0 )
{
dwRetCode = GetLastError();
PppLogError( ROUTERLOG_CANT_GET_REGKEYVALUES, 0, NULL, dwRetCode );
break;
}
pCpDllExpandedPath = (LPSTR)LOCAL_ALLOC( LPTR, ++cbSize );
if ( pCpDllExpandedPath == (LPSTR)NULL )
{
dwRetCode = GetLastError();
PppLogError( ROUTERLOG_NOT_ENOUGH_MEMORY, 0, NULL, dwRetCode);
break;
}
cbSize = ExpandEnvironmentStrings(
pCpDllPath,
pCpDllExpandedPath,
cbSize );
if ( cbSize == 0 )
{
dwRetCode = GetLastError();
PppLogError(ROUTERLOG_CANT_GET_REGKEYVALUES,0,NULL,dwRetCode);
break;
}
hInstance = LoadLibrary( pCpDllExpandedPath );
if ( hInstance == (HINSTANCE)NULL )
{
dwRetCode = GetLastError();
PppLogErrorString( ROUTERLOG_PPP_CANT_LOAD_DLL,1,
&pCpDllExpandedPath,dwRetCode, 1);
break;
}
pRasCpEnumProtocolIds = GetProcAddress( hInstance,
"RasCpEnumProtocolIds" );
if ( pRasCpEnumProtocolIds == (FARPROC)NULL )
{
dwRetCode = GetLastError();
PppLogErrorString( ROUTERLOG_PPPCP_DLL_ERROR, 1,
&pCpDllExpandedPath, dwRetCode, 1);
break;
}
pCpDlls[dwKeyIndex].pRasCpEnumProtocolIds = pRasCpEnumProtocolIds;
dwRetCode = (DWORD) (*pRasCpEnumProtocolIds)( ProtocolIds, &dwNumProtocolIds );
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(ROUTERLOG_PPPCP_DLL_ERROR, 1,
&pCpDllExpandedPath, dwRetCode, 1);
break;
}
(*pcTotalNumProtocols) += dwNumProtocolIds;
pRasCpGetInfo = GetProcAddress( hInstance, "RasCpGetInfo" );
if ( pRasCpGetInfo == (FARPROC)NULL )
{
dwRetCode = GetLastError();
PppLogErrorString(ROUTERLOG_PPPCP_DLL_ERROR, 1,
&pCpDllExpandedPath, dwRetCode, 1);
break;
}
pCpDlls[dwKeyIndex].pRasCpGetInfo = pRasCpGetInfo;
RegCloseKey( hKeyCp );
hKeyCp = (HKEY)NULL;
pCpDlls[dwKeyIndex].pszModuleName = pCpDllExpandedPath;
pCpDlls[dwKeyIndex].hInstance = hInstance;
if ( NULL != pCpDllPath )
LOCAL_FREE( pCpDllPath );
pCpDllPath = (LPSTR)NULL;
}
if ( hKeyCp != (HKEY)NULL )
RegCloseKey( hKeyCp );
if ( pCpDllPath != (LPSTR)NULL )
LOCAL_FREE( pCpDllPath );
return( dwRetCode );
}
//**
//
// Call: ReadPPPKeyValues
//
// Returns: NO_ERROR - Success
// Non-zero - Failure
//
// Description: Will read in all the values in the PPP key.
//
DWORD
ReadPPPKeyValues(
IN HKEY hKeyPpp
)
{
DWORD dwIndex;
DWORD dwRetCode;
DWORD cbValueBuf;
DWORD dwType;
//
// Run through and get all the PPP values
//
for ( dwIndex = 0; PppRegParams[dwIndex].pszValueName != NULL; dwIndex++ )
{
cbValueBuf = sizeof( DWORD );
dwRetCode = RegQueryValueEx(
hKeyPpp,
PppRegParams[dwIndex].pszValueName,
NULL,
&dwType,
(LPBYTE)(PppRegParams[dwIndex].pValue),
&cbValueBuf
);
if ((dwRetCode != NO_ERROR) && (dwRetCode != ERROR_FILE_NOT_FOUND))
{
PppLogError(ROUTERLOG_CANT_GET_REGKEYVALUES,0,NULL,dwRetCode);
break;
}
if ( dwRetCode == ERROR_FILE_NOT_FOUND )
{
*(PppRegParams[dwIndex].pValue) = PppRegParams[dwIndex].dwDefValue;
dwRetCode = NO_ERROR;
}
else
{
if ( ( dwType != REG_DWORD ) ||
( *(PppRegParams[dwIndex].pValue) > PppRegParams[dwIndex].Max))
{
CHAR * pChar = PppRegParams[dwIndex].pszValueName;
PppLogWarning(ROUTERLOG_REGVALUE_OVERIDDEN, 1,&pChar);
*(PppRegParams[dwIndex].pValue)
= PppRegParams[dwIndex].dwDefValue;
}
}
}
if ( dwRetCode != NO_ERROR )
{
return( ERROR_REGISTRY_CORRUPT );
}
//
// If value is zero use defaults.
//
if ( PppConfigInfo.MaxTerminate == 0 )
{
PppConfigInfo.MaxTerminate = PPP_DEF_MAXTERMINATE;
}
if ( PppConfigInfo.MaxFailure == 0 )
{
PppConfigInfo.MaxFailure = PPP_DEF_MAXFAILURE;
}
if ( PppConfigInfo.MaxConfigure == 0 )
{
PppConfigInfo.MaxConfigure = PPP_DEF_MAXCONFIGURE;
}
if ( PppConfigInfo.MaxReject == 0 )
{
PppConfigInfo.MaxReject = PPP_DEF_MAXREJECT;
}
//
// Really the number for request retries so subtract one.
//
PppConfigInfo.MaxTerminate--;
PppConfigInfo.MaxConfigure--;
return( NO_ERROR );
}
//**
//
// Call: ReadRegistryInfo
//
// Returns: NO_ERROR - Success
// non-zero WIN32 error - failure
//
// Description: Will read all PPP information in the registry. Will load the
// control and authentication protocol dlls and
// initialze the CpTable with information about the protocols.
//
DWORD
ReadRegistryInfo(
OUT HKEY * phKeyPpp
)
{
HKEY hKeyProtocols = (HKEY)NULL;
DWORD dwNumSubKeys = 0;
DWORD dwMaxSubKeySize;
DWORD dwNumValues;
DWORD cbMaxValNameLen;
DWORD cbMaxValueDataSize;
DWORD dwSecDescLen;
FILETIME LastWrite;
DWORD dwRetCode;
DWORD ProtocolIds[PPPCP_MAXCPSPERDLL];
DWORD dwNumProtocolIds;
DWORD cTotalNumProtocols = 0;
PPPCP_ENTRY CpEntry;
DWORD dwIndex;
DWORD cbValueBuf;
DWORD dwType;
DWORD dwValue;
do
{
dwRetCode = RegOpenKeyEx(
HKEY_LOCAL_MACHINE,
RAS_KEYPATH_PPP,
0,
KEY_READ,
phKeyPpp );
if ( dwRetCode != NO_ERROR)
{
PppLogErrorString(ROUTERLOG_CANT_OPEN_PPP_REGKEY,0,NULL,
dwRetCode,0);
break;
}
dwRetCode = RegOpenKeyEx(
HKEY_LOCAL_MACHINE,
RAS_KEYPATH_PROTOCOLS,
0,
KEY_READ,
&hKeyProtocols );
if ( dwRetCode != NO_ERROR)
{
PppLogErrorString(ROUTERLOG_CANT_OPEN_PPP_REGKEY,0,NULL,
dwRetCode,0);
break;
}
//
// Find out how many sub-keys or dlls there are
//
dwRetCode = RegQueryInfoKey(
hKeyProtocols,
NULL,
NULL,
NULL,
&dwNumSubKeys,
&dwMaxSubKeySize,
NULL,
&dwNumValues,
&cbMaxValNameLen,
&cbMaxValueDataSize,
NULL,
NULL
);
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(ROUTERLOG_CANT_OPEN_PPP_REGKEY,0,
NULL,dwRetCode,0);
break;
}
//
// Cannot have no APs or NCPs
//
if ( dwNumSubKeys == 0 )
{
PppLogError( ROUTERLOG_NO_AUTHENTICATION_CPS, 0, NULL, 0 );
dwRetCode = ERROR_REGISTRY_CORRUPT;
break;
}
dwRetCode = ReadPPPKeyValues( *phKeyPpp );
if ( dwRetCode != NO_ERROR )
{
break;
}
LoadParserDll( PppConfigInfo.hKeyPpp );
//
// Allocate space to hold entry points for all the CP dlls
//
pCpDlls = (DLL_ENTRY_POINTS*)LOCAL_ALLOC( LPTR,
sizeof( DLL_ENTRY_POINTS )
* (dwNumSubKeys + 1) );
if ( pCpDlls == (DLL_ENTRY_POINTS*)NULL )
{
dwRetCode = GetLastError();
PppLogError( ROUTERLOG_NOT_ENOUGH_MEMORY, 0, NULL, dwRetCode );
break;
}
pCpDlls[dwNumSubKeys].hInstance = INVALID_HANDLE_VALUE;
//
// Load all the AP and CP dlls and get their entry points
//
dwRetCode = LoadProtocolDlls(
pCpDlls,
dwNumSubKeys,
hKeyProtocols,
&cTotalNumProtocols );
if ( dwRetCode != NO_ERROR )
break;
//
// We now know how big the CpTable structure has to be so allocate space
// for it. Add one for LCP.
//
CpTable = (PPPCP_ENTRY *)LOCAL_ALLOC( LPTR, sizeof( PPPCP_ENTRY ) *
( cTotalNumProtocols + 1 ) );
if ( CpTable == (PPPCP_ENTRY *)NULL)
{
dwRetCode = GetLastError();
PppLogError( ROUTERLOG_NOT_ENOUGH_MEMORY, 0, NULL, dwRetCode );
break;
}
//
// Now fill up the table. First fill up information for LCP
//
dwRetCode = LcpGetInfo( PPP_LCP_PROTOCOL,
&(CpTable[LCP_INDEX].CpInfo) );
if ( dwRetCode != NO_ERROR )
{
CHAR * pChar = "LCP";
PppLogErrorString(ROUTERLOG_PPPCP_DLL_ERROR, 1,
&pChar, dwRetCode, 1);
break;
}
PppConfigInfo.NumberOfCPs = 1;
PppConfigInfo.NumberOfAPs = 0;
//
// Fill up the table with the loaded APs and CPs. The CPs start from
// 1 and increase the APs start from cTotolNumProtocols and go down.
//
for ( dwIndex = 0; dwIndex < dwNumSubKeys; dwIndex++ )
{
dwRetCode = (DWORD)(pCpDlls[dwIndex].pRasCpEnumProtocolIds)(
ProtocolIds,
&dwNumProtocolIds );
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(
ROUTERLOG_PPPCP_DLL_ERROR,
1,
&(pCpDlls[dwIndex].pszModuleName),
dwRetCode,
1 );
break;
}
if ( ( dwNumProtocolIds == 0 ) ||
( dwNumProtocolIds > PPPCP_MAXCPSPERDLL ) )
{
dwRetCode = ERROR_INVALID_PARAMETER;
PppLogErrorString(
ROUTERLOG_PPPCP_DLL_ERROR,
1,
&(pCpDlls[dwIndex].pszModuleName),
dwRetCode,
1 );
break;
}
while( dwNumProtocolIds-- > 0 )
{
ZeroMemory( &CpEntry, sizeof( CpEntry ) );
dwRetCode = (DWORD)(pCpDlls[dwIndex].pRasCpGetInfo)(
ProtocolIds[dwNumProtocolIds],
&CpEntry.CpInfo );
if ( dwRetCode != NO_ERROR )
{
PppLogErrorString(
ROUTERLOG_PPPCP_DLL_ERROR,
1,
&(pCpDlls[dwIndex].pszModuleName),
dwRetCode,
1 );
break;
}
if ( CpEntry.CpInfo.Protocol == PPP_IPCP_PROTOCOL )
{
PppConfigInfo.RasIpcpDhcpInform =
(DWORD(*)(VOID*, PPP_DHCP_INFORM*))
IpcpDhcpInform;
PppConfigInfo.RasIphlpDhcpCallback =
(VOID(*)(ULONG))
RasSrvrDhcpCallback;
}
if ( CpEntry.CpInfo.RasCpInit != NULL )
{
if ( (PPP_IPCP_PROTOCOL == CpEntry.CpInfo.Protocol)
|| (PPP_IPXCP_PROTOCOL == CpEntry.CpInfo.Protocol)
|| (PPP_NBFCP_PROTOCOL == CpEntry.CpInfo.Protocol)
|| (PPP_ATCP_PROTOCOL == CpEntry.CpInfo.Protocol)
)
{
// Do not init the CP.
}
else
{
PppLog(1, "RasCpInit(%x, TRUE)", CpEntry.CpInfo.Protocol);
dwRetCode = CpEntry.CpInfo.RasCpInit(
TRUE/* fInitialize */);
CpEntry.fFlags |= PPPCP_FLAG_INIT_CALLED;
if ( dwRetCode != NO_ERROR )
{
CHAR* SubStringArray[2];
SubStringArray[0] = CpEntry.CpInfo.SzProtocolName;
SubStringArray[1] = pCpDlls[dwIndex].pszModuleName;
PppLogErrorString(
ROUTERLOG_PPPCP_INIT_ERROR,
2,
SubStringArray,
dwRetCode,
2 );
break;
}
else
{
CpEntry.fFlags |= PPPCP_FLAG_AVAILABLE;
}
}
}
//
// If this entry point is NULL we assume that this is a CP.
//
if ( CpEntry.CpInfo.RasApMakeMessage == NULL )
{
if ( ( CpEntry.CpInfo.RasCpBegin == NULL ) ||
( CpEntry.CpInfo.RasCpEnd == NULL ) ||
( CpEntry.CpInfo.RasCpReset == NULL ) ||
( CpEntry.CpInfo.RasCpMakeConfigRequest == NULL ) ||
( CpEntry.CpInfo.RasCpMakeConfigResult == NULL ) ||
( CpEntry.CpInfo.RasCpConfigAckReceived == NULL ) ||
( CpEntry.CpInfo.RasCpConfigNakReceived == NULL ) ||
( CpEntry.CpInfo.RasCpConfigRejReceived == NULL ) ||
( CpEntry.CpInfo.Recognize > ( DISCARD_REQ + 1) ) )
{
dwRetCode = ERROR_INVALID_PARAMETER;
PppLogErrorString(
ROUTERLOG_PPPCP_DLL_ERROR,
1,
&(pCpDlls[dwIndex].pszModuleName),
dwRetCode,
1 );
break;
}
CpTable[PppConfigInfo.NumberOfCPs++] = CpEntry;
}
else
{
CpTable[cTotalNumProtocols-PppConfigInfo.NumberOfAPs]
= CpEntry;
PppConfigInfo.NumberOfAPs++;
}
}
if ( dwRetCode != NO_ERROR )
break;
}
if ( GetCpIndexFromProtocol( PPP_BACP_PROTOCOL ) == (DWORD)-1 )
{
PppConfigInfo.ServerConfigInfo.dwConfigMask &= ~PPPCFG_NegotiateBacp;
}
else if ( PppConfigInfo.ServerConfigInfo.dwConfigMask &
PPPCFG_NegotiateBacp )
{
cbValueBuf = sizeof(DWORD);
if (RegQueryValueEx(
*phKeyPpp, RAS_VALUENAME_DOBAPONVPN,
NULL, &dwType,
(LPBYTE )&dwValue, &cbValueBuf ) == 0
&& dwType == REG_DWORD
&& cbValueBuf == sizeof(DWORD)
&& dwValue)
{
FDoBapOnVpn = TRUE;
BapTrace( "Allowing BAP over VPN's" );
}
}
} while( FALSE );
if ( dwRetCode != NO_ERROR )
{
if ( CpTable != (PPPCP_ENTRY *)NULL )
{
LOCAL_FREE( CpTable );
}
}
if ( hKeyProtocols != (HKEY)NULL )
{
RegCloseKey( hKeyProtocols );
}
if ( pCpDlls != (DLL_ENTRY_POINTS*)NULL )
{
for ( dwIndex = 0; dwIndex < dwNumSubKeys; dwIndex++ )
{
if ( pCpDlls[dwIndex].pszModuleName != (LPSTR)NULL )
{
LOCAL_FREE( pCpDlls[dwIndex].pszModuleName );
}
}
if ( dwRetCode != NO_ERROR )
{
LOCAL_FREE( pCpDlls );
pCpDlls = NULL;
}
}
return( dwRetCode );
}
//**
//
// Call: InitializePPP
//
// Returns: NO_ERROR - Success
// non-zero code - Failure
//
// Description: Will initialize all global data and load and initialize the
// Control and Authentication protocol dll.s
//
DWORD
InitializePPP(
VOID
)
{
DWORD dwIndex;
DWORD dwTId;
DWORD dwRetCode;
HANDLE hThread;
NT_PRODUCT_TYPE NtProductType;
srand ( (unsigned int)time ( NULL ) );
PppConfigInfo.dwTraceId = TraceRegisterA( "PPP" );
DwBapTraceId = TraceRegisterA( "BAP" );
// PrivateTraceId = TraceRegisterA( "Private" );
PppConfigInfo.hLogEvents = RouterLogRegister( TEXT("RemoteAccess") );
PppConfigInfo.RasIpcpDhcpInform = NULL;
PppConfigInfo.RasIphlpDhcpCallback = NULL;
PppConfigInfo.dwLoggingLevel = 3;
//
// Create DDM private heap
//
PppConfigInfo.hHeap = HeapCreate( 0, PPP_HEAP_INITIAL_SIZE,
PPP_HEAP_MAX_SIZE );
if ( PppConfigInfo.hHeap == NULL )
{
return( GetLastError() );
}
if ( (dwRetCode = ReadRegistryInfo(&(PppConfigInfo.hKeyPpp))) != NO_ERROR )
{
return( dwRetCode );
}
dwRetCode = InitEndpointDiscriminator(PppConfigInfo.EndPointDiscriminator);
if ( dwRetCode != NO_ERROR )
{
return( dwRetCode );
}
PppConfigInfo.PortUIDGenerator = 0;
//
// Initialize global data-structures
//
//
// Allocate hash table for PCBs
//
PcbTable.PcbBuckets = LOCAL_ALLOC( LPTR,
sizeof( PCB_BUCKET ) *
PcbTable.NumPcbBuckets );
if ( PcbTable.PcbBuckets == NULL )
{
return( GetLastError() );
}
//
// Allocate hash table for BCBs
//
PcbTable.BcbBuckets = LOCAL_ALLOC( LPTR,
sizeof( BCB_BUCKET ) *
PcbTable.NumPcbBuckets );
if ( PcbTable.BcbBuckets == NULL )
{
LOCAL_FREE( PcbTable.PcbBuckets );
return( GetLastError() );
}
for( dwIndex = 0; dwIndex < PcbTable.NumPcbBuckets; dwIndex++ )
{
PcbTable.PcbBuckets[dwIndex].pPorts = (PCB *)NULL;
PcbTable.BcbBuckets[dwIndex].pBundles = (BCB *)NULL;
}
WorkItemQ.pQHead = (PCB_WORK_ITEM*)NULL;
WorkItemQ.pQTail = (PCB_WORK_ITEM*)NULL;
InitializeCriticalSection( &(WorkItemQ.CriticalSection) );
WorkItemQ.hEventNonEmpty = CreateEvent( NULL, TRUE, FALSE, NULL );
if ( WorkItemQ.hEventNonEmpty == (HANDLE)NULL )
{
return( GetLastError() );
}
TimerQ.hEventNonEmpty = CreateEvent( NULL, FALSE, FALSE, NULL );
if ( TimerQ.hEventNonEmpty == (HANDLE)NULL )
{
return( GetLastError() );
}
PppConfigInfo.hEventChangeNotification = CreateEvent(NULL,FALSE,FALSE,NULL);
if ( PppConfigInfo.hEventChangeNotification == (HANDLE)NULL )
{
return( GetLastError() );
}
RtlGetNtProductType( &NtProductType );
if ( NtProductWinNt == NtProductType )
{
PppConfigInfo.fFlags |= PPPCONFIG_FLAG_WKSTA;
}
//
// Create worker thread.
//
hThread = CreateThread( NULL, 0, WorkerThread, NULL, 0, &dwTId );
if ( hThread == (HANDLE)NULL )
{
return( GetLastError() );
}
CloseHandle(hThread);
return( NO_ERROR );
}
//**
//
// Call: PPPCleanUp
//
// Returns: NO_ERROR - Success
// Non-zero returns - Failure
//
// Description: Will de-allocate all allocated memory, close all handles and
// reset all the global structures to 0.
//
VOID
PPPCleanUp(
VOID
)
{
DWORD dwIndex;
DWORD dwError;
DWORD cTotalNumProtocols;
//
// Unload DLLs.
//
cTotalNumProtocols = PppConfigInfo.NumberOfCPs + PppConfigInfo.NumberOfAPs;
if ( pCpDlls != NULL )
{
for ( dwIndex = 0; dwIndex < cTotalNumProtocols; dwIndex++ )
{
if ( CpTable[dwIndex].fFlags & PPPCP_FLAG_INIT_CALLED )
{
PppLog( 1, "RasCpInit(%x, FALSE)",
CpTable[dwIndex].CpInfo.Protocol );
dwError = CpTable[dwIndex].CpInfo.RasCpInit(
FALSE /* fInitialize */ );
if ( NO_ERROR != dwError )
{
PppLog(
1,
"RasCpInit(FALSE) for protocol 0x%x returned error %d",
CpTable[dwIndex].CpInfo.Protocol,
dwError );
}
CpTable[dwIndex].fFlags &= ~PPPCP_FLAG_INIT_CALLED;
CpTable[dwIndex].fFlags &= ~PPPCP_FLAG_AVAILABLE;
}
}
for ( dwIndex = 0;
pCpDlls[dwIndex].hInstance != INVALID_HANDLE_VALUE;
dwIndex++ )
{
if ( pCpDlls[dwIndex].hInstance != NULL )
{
FreeLibrary( pCpDlls[dwIndex].hInstance );
}
}
if ( pCpDlls )
LOCAL_FREE( pCpDlls );
pCpDlls = NULL;
}
RouterLogDeregister( PppConfigInfo.hLogEvents );
DeleteCriticalSection( &(WorkItemQ.CriticalSection) );
if ( TimerQ.hEventNonEmpty != NULL )
{
CloseHandle( TimerQ.hEventNonEmpty );
}
if ( WorkItemQ.hEventNonEmpty != NULL )
{
CloseHandle( WorkItemQ.hEventNonEmpty );
}
if ( PppConfigInfo.hEventChangeNotification != NULL )
{
CloseHandle( PppConfigInfo.hEventChangeNotification );
}
//
// Destroy private heap
//
if ( PppConfigInfo.hHeap != NULL )
{
HeapDestroy( PppConfigInfo.hHeap );
}
if ( PppConfigInfo.dwTraceId != INVALID_TRACEID )
{
TraceDeregisterA( PppConfigInfo.dwTraceId );
}
if ( PppConfigInfo.hKeyPpp != (HKEY)NULL )
{
RegCloseKey( PppConfigInfo.hKeyPpp );
}
if ( NULL != PppConfigInfo.hInstanceParserDll )
{
FreeLibrary( PppConfigInfo.hInstanceParserDll );
}
if (NULL != PppConfigInfo.pszParserDllPath)
{
LOCAL_FREE(PppConfigInfo.pszParserDllPath);
}
PppConfigInfo.pszParserDllPath = NULL;
PppConfigInfo.PacketFromPeer = NULL;
PppConfigInfo.PacketToPeer = NULL;
PppConfigInfo.PacketFree = NULL;
//
// TraceDeregisterA can handle INVALID_TRACEID gracefully
//
TraceDeregisterA( DwBapTraceId );
ZeroMemory( &PcbTable, sizeof( PcbTable ) );
ZeroMemory( &WorkItemQ, sizeof( WorkItemQ ) );
ZeroMemory( &PppConfigInfo, sizeof( PppConfigInfo ) );
ZeroMemory( &TimerQ, sizeof( TimerQ ) );
CpTable = NULL;
}
//**
//
// Call: DllEntryPoint
//
// Returns: TRUE - Success
// FALSE - Failure
//
// Description:
//
BOOL
DllEntryPoint(
IN HANDLE hInstDLL,
IN DWORD fdwReason,
IN LPVOID lpvReserved
)
{
switch (fdwReason)
{
case DLL_PROCESS_ATTACH:
HInstDLL = hInstDLL;
DisableThreadLibraryCalls(hInstDLL);
break;
}
return(TRUE);
}
//**
//
// Call: RasCpEnumProtocolIds
//
// Returns: NO_ERROR - Success
//
// Description: This entry point is called to enumerate the number and the
// control protocol Ids for the protocols contained in the module.
//
DWORD
RasCpEnumProtocolIds(
OUT DWORD * pdwProtocolIds,
IN OUT DWORD * pcProtocolIds
)
{
DWORD dwIndex;
HKEY hKey;
DWORD dwErr;
DWORD dwType;
DWORD dwValue;
DWORD dwSize;
PppLog(1, "RasCpEnumProtocolIds");
RTASSERT(NUM_BUILT_IN_CPS <= PPPCP_MAXCPSPERDLL);
*pcProtocolIds = 0;
dwErr = RegOpenKeyEx(HKEY_LOCAL_MACHINE, RAS_KEYPATH_BUILTIN, 0, KEY_READ,
&hKey);
if (ERROR_SUCCESS == dwErr)
{
for (dwIndex = 0; dwIndex < NUM_BUILT_IN_CPS; dwIndex++)
{
dwSize = sizeof(dwValue);
dwErr = RegQueryValueEx(hKey, BuiltInCps[dwIndex].szNegotiateCp,
NULL, &dwType, (BYTE*)&dwValue, &dwSize);
if ( ERROR_SUCCESS == dwErr
&& REG_DWORD == dwType
&& sizeof(DWORD) == dwSize
&& !dwValue)
{
BuiltInCps[dwIndex].fLoad = FALSE;
PppLog(1, "%s is FALSE", BuiltInCps[dwIndex].szNegotiateCp);
}
}
RegCloseKey(hKey);
}
for (dwIndex = 0; dwIndex < NUM_BUILT_IN_CPS; dwIndex++)
{
if (BuiltInCps[dwIndex].fLoad)
{
pdwProtocolIds[*pcProtocolIds] = BuiltInCps[dwIndex].dwProtocolId;
PppLog(1, "Protocol %x", BuiltInCps[dwIndex].dwProtocolId);
*pcProtocolIds += 1;
}
}
return(NO_ERROR);
}
//**
//
// Call: RasCpGetInfo
//
// Returns: NO_ERROR - Success
// ERROR_INVALID_PARAMETER - Protocol id is unrecogized
//
// Description: This entry point is called for get all information for the
// control protocol in this module.
//
DWORD
RasCpGetInfo(
IN DWORD dwProtocolId,
OUT PPPCP_INFO* pCpInfo
)
{
DWORD dwIndex;
PppLog(1, "RasCpGetInfo %x", dwProtocolId);
for (dwIndex = 0; dwIndex < NUM_BUILT_IN_CPS; dwIndex++)
{
if ( (BuiltInCps[dwIndex].dwProtocolId == dwProtocolId)
&& BuiltInCps[dwIndex].fLoad)
{
return((DWORD)BuiltInCps[dwIndex].pRasCpGetInfo(
dwProtocolId, pCpInfo));
}
}
return(ERROR_INVALID_PARAMETER);
}
VOID
PrivateTrace(
IN CHAR* Format,
...
)
{
va_list arglist;
va_start(arglist, Format);
TraceVprintfEx(PrivateTraceId,
0x00010000 | TRACE_USE_MASK | TRACE_USE_MSEC,
Format,
arglist);
va_end(arglist);
}