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windows-nt/Source/XPSP1/NT/net/wins/mib/winsmib.c
CryptoAlgo Inc b3cac27891 Add source files
2020-09-26 16:20:57 +08:00

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//
// TODO: Make it multithreaded
//
/*++ BUILD Version: 0001 // Increment this if a change has global effects
Copyright (c) 1991 Microsoft Corporation
Module Name:
winsmib.c
Abstract:
Sample SNMP Extension Agent for Windows NT.
These files (testdll.c, winsmib.c, and winsmib.h) provide an example of
how to structure an Extension Agent DLL which works in conjunction with
the SNMP Extendible Agent for Windows NT.
Extensive comments have been included to describe its structure and
operation. See also "Microsoft Windows/NT SNMP Programmer's Reference".
Created:
7-Oct-1991
Revision History:
--*/
#ifdef UNICODE
#undef UNICODE
#endif
// This Extension Agent implements the Internet toaster MIB. It's
// definition follows here:
//
//
// Necessary includes.
#include "wins.h"
#include <malloc.h>
#include <snmp.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <time.h>
#include <search.h>
#include <winsock2.h>
#include "nmsdb.h"
//#include "winsif.h"
#include "winsintf.h"
#include "winscnf.h"
#include "nmsmsgf.h"
// Contains definitions for the table structure describing the MIB. This
// is used in conjunction with winsmib.c where the MIB requests are resolved.
#include "winsmib.h"
// If an addition or deletion to the MIB is necessary, there are several
// places in the code that must be checked and possibly changed.
//
// The last field in each MIB entry is used to point to the NEXT
// leaf variable. If an addition or deletetion is made, these pointers
// may need to be updated to reflect the modification.
#define _WINS_CNF_KEY TEXT("System\\CurrentControlSet\\Services\\Wins")
#define _WINS_PARAMETERS_KEY TEXT("Parameters")
#define _WINS_PARTNERS_KEY TEXT("Partners")
#define _WINS_DATAFILES_KEY TEXT("Datafiles")
#define _WINS_PULL_KEY TEXT("Pull")
#define _WINS_PUSH_KEY TEXT("Push")
#define NO_FLDS_IN_PULLADD_KEY 8 //Flds are ip add, time interval, sp time
#define NO_FLDS_IN_PUSHADD_KEY 2 //Flds are ip add, update count
#define NO_FLDS_IN_DR 5 //Flds in a data record
#define LOCAL_ADD "127.0.0.1"
#define WINSMIB_FILE_INFO_SIZE 255
#define WINSMIB_DR_CACHE_TIME (120) //2 minutes
BOOL fWinsMibWinsKeyOpen = FALSE;
HKEY WinsMibWinsKey;
STATIC HKEY sParametersKey;
STATIC HKEY sPartnersKey;
STATIC HKEY sPullKey;
STATIC HKEY sPushKey;
STATIC HKEY sDatafilesKey;
STATIC BOOL sfParametersKeyOpen = FALSE;
STATIC BOOL sfPartnersKeyOpen = FALSE;
STATIC BOOL sfDatafilesKeyOpen = FALSE;
STATIC BOOL sfPullKeyOpen = FALSE;
STATIC BOOL sfPushKeyOpen = FALSE;
STATIC time_t sDRCacheInitTime = 0;
//
// The prefix to all of the WINS MIB variables is 1.3.6.1.4.1.311.1.2
//
// The last digit -- 2 is for the WINS MIB
//
UINT OID_Prefix[] = { 1, 3, 6, 1, 4, 1, 311, 1 , 2};
AsnObjectIdentifier MIB_OidPrefix = { OID_SIZEOF(OID_Prefix), OID_Prefix };
BOOL fWinsMibWinsStatusCnfCalled;
BOOL fWinsMibWinsStatusStatCalled;
WINSINTF_BIND_DATA_T sBindData;
WINSINTF_RECS_T sRecs = {0};
//
// Definition of the Wins MIB (not used)
//
//UINT MIB_Wins[] = { 2 };
//
// OID definitions for MIB
//
//
// Definition of group and leaf variables under the wins group
// All leaf variables have a zero appended to their OID to indicate
// that it is the only instance of this variable and it exists.
//
UINT MIB_Parameters[] = { 1 };
UINT MIB_WinsStartTime[] = { 1, 1, 0 };
UINT MIB_LastPScvTime[] = { 1, 2, 0 };
UINT MIB_LastATScvTime[] = { 1, 3, 0 };
UINT MIB_LastTombScvTime[] = { 1, 4, 0 };
UINT MIB_LastVerifyScvTime[] = { 1, 5, 0 };
UINT MIB_LastPRplTime[] = { 1, 6, 0 };
UINT MIB_LastATRplTime[] = { 1, 7, 0 };
UINT MIB_LastNTRplTime[] = { 1, 8, 0 };
UINT MIB_LastACTRplTime[] = { 1, 9, 0 };
UINT MIB_LastInitDbTime[] = { 1, 10, 0 };
UINT MIB_LastCounterResetTime[] = { 1, 11, 0 };
UINT MIB_WinsTotalNoOfReg[] = { 1, 12, 0 };
UINT MIB_WinsTotalNoOfQueries[] = { 1, 13, 0 };
UINT MIB_WinsTotalNoOfRel[] = { 1, 14, 0 };
UINT MIB_WinsTotalNoOfSuccRel[] = { 1, 15, 0 };
UINT MIB_WinsTotalNoOfFailRel[] = { 1, 16, 0 };
UINT MIB_WinsTotalNoOfSuccQueries[] = { 1, 17, 0 };
UINT MIB_WinsTotalNoOfFailQueries[] = { 1, 18, 0 };
UINT MIB_RefreshInterval[] = { 1, 19, 0 };
UINT MIB_TombstoneInterval[] = { 1, 20, 0 };
UINT MIB_TombstoneTimeout[] = { 1, 21, 0 };
UINT MIB_VerifyInterval[] = { 1, 22, 0 };
UINT MIB_VersCounterStartVal_LowWord[] = { 1, 23, 0 };
UINT MIB_VersCounterStartVal_HighWord[] = { 1, 24, 0 };
UINT MIB_RplOnlyWCnfPnrs[] = { 1, 25, 0 };
UINT MIB_StaticDataInit[] = { 1, 26, 0 };
UINT MIB_LogFlag[] = { 1, 27, 0 };
UINT MIB_LogFileName[] = { 1, 28, 0 };
UINT MIB_BackupDirPath[] = { 1, 29, 0 };
UINT MIB_DoBackupOnTerm[] = { 1, 30, 0 };
UINT MIB_MigrateOn[] = { 1, 31, 0 };
//
// Pull mib vars
//
UINT MIB_Pull[] = { 2 };
UINT MIB_PullInitTime[] = { 2, 1, 0 };
UINT MIB_CommRetryCount[] = { 2, 2, 0 };
UINT MIB_PullPnrTable[] = { 2, 3};
UINT MIB_PullPnrTableEntry[] = { 2, 3, 1};
//
// Push mib vars
//
UINT MIB_Push[] = { 3 };
UINT MIB_PushInitTime[] = { 3, 1, 0 };
UINT MIB_RplOnAddChg[] = { 3, 2, 0 };
UINT MIB_PushPnrTable[] = { 3, 3};
UINT MIB_PushPnrTableEntry[] = { 3, 3, 1};
//
// Datafile mib vars
//
UINT MIB_Datafiles[] = { 4 };
UINT MIB_DatafilesTable[] = { 4 , 1};
UINT MIB_DatafilesTableEntry[] = { 4 , 1, 1};
//
// Cmd mib Vars
UINT MIB_Cmd[] = { 5 };
UINT MIB_PullTrigger[] = { 5, 1, 0};
UINT MIB_PushTrigger[] = { 5, 2, 0};
UINT MIB_DeleteWins[] = { 5, 3, 0};
UINT MIB_DoScavenging[] = { 5, 4, 0};
UINT MIB_DoStaticInit[] = { 5, 5, 0};
UINT MIB_NoOfWrkThds[] = { 5, 6, 0};
UINT MIB_PriorityClass[] = { 5, 7, 0};
UINT MIB_ResetCounters[] = { 5, 8, 0};
UINT MIB_DeleteDbRecs[] = { 5, 9, 0};
UINT MIB_GetDbRecs[] = { 5, 10, 0};
UINT MIB_DbRecsTable[] = { 5, 11};
UINT MIB_DbRecsTableEntry[] = { 5, 11, 1};
UINT MIB_MaxVersNo_LowWord[] = { 5, 12, 0 };
UINT MIB_MaxVersNo_HighWord[] = { 5, 13, 0 };
//
// //
// Storage definitions for MIB //
// //
// Parameters group
char MIB_WinsStartTimeStore[80];
char MIB_LastPScvTimeStore[80];
char MIB_LastATScvTimeStore[80];
char MIB_LastTombScvTimeStore[80];
char MIB_LastVerifyScvTimeStore[80];
char MIB_LastPRplTimeStore[80];
char MIB_LastATRplTimeStore[80];
char MIB_LastNTRplTimeStore[80];
char MIB_LastACTRplTimeStore[80];
char MIB_LastInitDbTimeStore[80];
char MIB_LastCounterResetTimeStore[80];
AsnCounter MIB_WinsTotalNoOfRegStore = 0;
AsnCounter MIB_WinsTotalNoOfQueriesStore = 0;
AsnCounter MIB_WinsTotalNoOfRelStore = 0;
AsnCounter MIB_WinsTotalNoOfSuccRelStore = 0;
AsnCounter MIB_WinsTotalNoOfFailRelStore = 0;
AsnCounter MIB_WinsTotalNoOfSuccQueriesStore = 0;
AsnCounter MIB_WinsTotalNoOfFailQueriesStore = 0;
AsnInteger MIB_RefreshIntervalStore = 0;
AsnInteger MIB_TombstoneIntervalStore = 0;
AsnInteger MIB_TombstoneTimeoutStore = 0;
AsnInteger MIB_VerifyIntervalStore = 0;
AsnCounter MIB_VersCounterStartVal_HighWordStore = 0;
AsnCounter MIB_VersCounterStartVal_LowWordStore = 0;
AsnInteger MIB_RplOnlyWCnfPnrsStore = 0;
AsnInteger MIB_StaticDataInitStore = 0;
AsnInteger MIB_LogFlagStore = 1;
char MIB_LogFileNameStore[256];
char MIB_BackupDirPathStore[256];
AsnInteger MIB_DoBackupOnTermStore = 0;
AsnInteger MIB_MigrateOnStore = 0;
//Pull
AsnInteger MIB_PullInitTimeStore = 1 ;
AsnInteger MIB_CommRetryCountStore = 0 ;
//PullPnr
char MIB_SpTimeStore[256];
AsnInteger MIB_TimeIntervalStore = 0 ;
AsnInteger MIB_MemberPrecStore = 0 ;
//Push
AsnInteger MIB_RplOnAddChgStore = 0;
//PushPnr
AsnInteger MIB_PushInitTimeStore = 0 ;
AsnInteger MIB_UpdateCountStore = 0 ;
//
// Cmd
//
char MIB_PullTriggerStore[10]; // double the size to store the old value in case of failure
char MIB_PushTriggerStore[10]; // double the size to store the old value in case of failure
char MIB_DeleteWinsStore[10];
AsnInteger MIB_DoScavengingStore;
char MIB_DoStaticInitStore[WINSMIB_FILE_INFO_SIZE] = {EOS};
AsnInteger MIB_NoOfWrkThdsStore;
AsnInteger MIB_PriorityClassStore;
AsnInteger MIB_ResetCountersStore;
char MIB_DeleteDbRecsStore[10];
char MIB_GetDbRecsStore[5] = {0};
AsnInteger MIB_MaxVersNo_LowWordStore;
AsnInteger MIB_MaxVersNo_HighWordStore;
CRITICAL_SECTION WinsMibCrtSec;
//
// Value Id.
//
// NOTE NOTE NOTE: The sequence must be the same as in VarInfo[]
//
typedef enum _VAL_ID_E {
//values for the Parameters Key
REF_INTVL_E = 0,
TOMB_INTVL_E,
TOMB_TMOUT_E,
VER_INTVL_E,
VERS_COUNT_LW_E,
VERS_COUNT_HW_E,
RPL_ONLY_W_CNF_PNRS_E,
STATIC_DATA_INIT_E,
LOG_FLAG_E,
LOG_FILE_NAME_E,
BACKUP_DIR_PATH_E,
DO_BACKUP_ON_TERM_E,
MIGRATE_ON_E,
//values for the Pull Key
COMM_RETRY_E,
PULL_INIT_TIME_E,
//values for pnrs under the pull key
SP_TIME_E,
TIME_INTVL_E,
MEMBER_PREC_E,
//values for the Push Key
PUSH_INIT_TIME_E,
//values for pnrs under the push key
RPL_ON_ADD_CHG_E,
UPD_CNT_E
} VAL_ID_E, *PVAL_ID_E;
//
// Holds information about partners (pull/push) used for accessing the
// Pull and Push partner tables
//
typedef struct _ADD_KEY_T {
BYTE asIpAddress[20];
DWORD IpAdd;
BYTE asSpTime[20];
BOOL fSpTimeSet;
union {
DWORD TimeInterval;
DWORD UpdateCount;
};
BOOL fTimeIntOrUpdCntSet;
DWORD MemberPrec;
DWORD NoOfRpls;
DWORD NoOfCommFails;
WINSINTF_VERS_NO_T VersNo;
} ADD_KEY_T, *PADD_KEY_T;
typedef struct _DATAFILE_INFO_T {
TCHAR FileNm[WINSMIB_FILE_INFO_SIZE];
DWORD StrType;
TCHAR ValNm[10];
} DATAFILE_INFO_T, *PDATAFILE_INFO_T;
#define DATAFILE_INFO_SZ sizeof(DATAFILE_INFO_T)
//
// holds info about variable used when accessing registry.
//
typedef struct _VAR_INFO_T {
LPDWORD pId; //Oid under WINS
LPBYTE pName;
LPVOID pStorage;
VAL_ID_E Val_Id_e;
DWORD ValType;
DWORD SizeOfData;
HKEY *pRootKey;
} VARINFO_T, *PVARINFO_T;
//
// This array comprises of stuff that needs to be read from/written to
// the registry.
//
VARINFO_T VarInfo[] = {
{
&MIB_RefreshInterval[1],
{ WINSCNF_REFRESH_INTVL_NM },
&MIB_RefreshIntervalStore,
REF_INTVL_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_TombstoneInterval[1],
WINSCNF_TOMBSTONE_INTVL_NM,
&MIB_TombstoneIntervalStore,
TOMB_INTVL_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_TombstoneTimeout[1],
WINSCNF_TOMBSTONE_TMOUT_NM,
&MIB_TombstoneTimeoutStore,
TOMB_TMOUT_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_VerifyInterval[1],
WINSCNF_VERIFY_INTVL_NM,
&MIB_VerifyIntervalStore,
VER_INTVL_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_VersCounterStartVal_LowWord[1],
WINSCNF_INIT_VERSNO_VAL_LW_NM,
&MIB_VersCounterStartVal_LowWordStore,
VERS_COUNT_LW_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_VersCounterStartVal_HighWord[1],
WINSCNF_INIT_VERSNO_VAL_HW_NM,
&MIB_VersCounterStartVal_HighWordStore,
VERS_COUNT_HW_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_RplOnlyWCnfPnrs[1],
WINSCNF_RPL_ONLY_W_CNF_PNRS_NM,
&MIB_RplOnlyWCnfPnrsStore,
RPL_ONLY_W_CNF_PNRS_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_StaticDataInit[1],
WINSCNF_STATIC_INIT_FLAG_NM,
&MIB_StaticDataInitStore,
STATIC_DATA_INIT_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_LogFlag[1],
WINSCNF_LOG_FLAG_NM,
&MIB_LogFlagStore,
LOG_FLAG_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_LogFileName[1],
WINSCNF_LOG_FILE_PATH_NM,
&MIB_LogFileNameStore,
LOG_FILE_NAME_E,
REG_EXPAND_SZ,
sizeof(MIB_LogFileNameStore),
&sParametersKey
},
{
&MIB_BackupDirPath[1],
WINSCNF_BACKUP_DIR_PATH_NM,
&MIB_BackupDirPathStore,
BACKUP_DIR_PATH_E,
REG_EXPAND_SZ,
sizeof(MIB_BackupDirPathStore),
&sParametersKey
},
{
&MIB_DoBackupOnTerm[1],
WINSCNF_DO_BACKUP_ON_TERM_NM,
&MIB_DoBackupOnTermStore,
DO_BACKUP_ON_TERM_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_MigrateOn[1],
WINSCNF_MIGRATION_ON_NM,
&MIB_MigrateOnStore,
MIGRATE_ON_E,
REG_DWORD,
sizeof(DWORD),
&sParametersKey
},
{
&MIB_CommRetryCount[1],
WINSCNF_RETRY_COUNT_NM,
&MIB_CommRetryCountStore,
COMM_RETRY_E,
REG_DWORD,
sizeof(DWORD),
&sPullKey
},
{
&MIB_PullInitTime[1],
WINSCNF_INIT_TIME_RPL_NM,
&MIB_PullInitTimeStore,
PULL_INIT_TIME_E,
REG_DWORD,
sizeof(DWORD),
&sPullKey
},
{
NULL, //&MIB_SpTime[1]
WINSCNF_SP_TIME_NM,
&MIB_SpTimeStore,
SP_TIME_E,
REG_SZ,
sizeof(MIB_SpTimeStore),
&sPullKey
},
{
NULL, //&MIB_TimeInterval[1]
WINSCNF_RPL_INTERVAL_NM,
&MIB_TimeIntervalStore,
TIME_INTVL_E,
REG_DWORD,
sizeof(DWORD),
&sPullKey
},
{
NULL,
WINSCNF_MEMBER_PREC_NM,
&MIB_MemberPrecStore,
MEMBER_PREC_E,
REG_DWORD,
sizeof(DWORD),
&sPullKey
},
{
&MIB_PushInitTime[1],
WINSCNF_INIT_TIME_RPL_NM,
&MIB_PushInitTimeStore,
PUSH_INIT_TIME_E,
REG_DWORD,
sizeof(DWORD),
&sPushKey
},
{
&MIB_RplOnAddChg[1],
WINSCNF_ADDCHG_TRIGGER_NM,
&MIB_RplOnAddChgStore,
RPL_ON_ADD_CHG_E,
REG_DWORD,
sizeof(DWORD),
&sPushKey
},
{
NULL, //&MIB_UpdateCount[1]
WINSCNF_UPDATE_COUNT_NM,
&MIB_UpdateCountStore,
UPD_CNT_E,
REG_DWORD,
sizeof(DWORD),
&sPushKey
}
};
//
// Type of key
//
typedef enum _KEY_TYPE_E {
PARAMETERS_E_KEY,
PARTNERS_E_KEY,
DATAFILES_E_KEY,
PULL_E_KEY,
PUSH_E_KEY,
IPADD_E_KEY
} KEY_TYPE_E, *PKEY_TYPE_E;
//
// Determines if the MIB variable falls in the range requiring access to the
// the registry
//
#define PARAMETERS_VAL_M(pMib) ( \
((pMib)->Oid.ids[0] == 1) \
&& \
((pMib)->Oid.ids[1] >= 19) \
&& \
((pMib)->Oid.ids[1] <= 31) \
)
//
// All MIB variables in the common group have 1 as their first id
//
#define COMMON_VAL_M(pMib) ((pMib)->Oid.ids[0] == 1)
//
// All MIB variables in the common group have 2 as their first id
//
#define PULL_VAL_M(pMib) ((pMib)->Oid.ids[0] == 2)
//
// All MIB variables in the common group have 3 as their first id
//
#define PUSH_VAL_M(pMib) ((pMib)->Oid.ids[0] == 3)
//
// Finds the enumerator corresponding to the registry parameter
//
#define PARAMETERS_ID_M(pMib, Val_Id_e) { \
if(pMib->Storage==&MIB_RefreshIntervalStore) { Val_Id_e = REF_INTVL_E; }else{\
if(pMib->Storage==&MIB_TombstoneIntervalStore){ Val_Id_e=TOMB_INTVL_E;}else{\
if(pMib->Storage==&MIB_TombstoneTimeoutStore) { Val_Id_e=TOMB_TMOUT_E; }else{\
if(pMib->Storage==&MIB_VerifyIntervalStore) { Val_Id_e = VER_INTVL_E; } else{\
if (pMib->Storage==&MIB_VersCounterStartVal_LowWordStore) { Val_Id_e = VERS_COUNT_LW_E; } else{ \
if (pMib->Storage == &MIB_VersCounterStartVal_HighWordStore) { Val_Id_e = VERS_COUNT_HW_E; } else{ \
if (pMib->Storage == &MIB_RplOnlyWCnfPnrsStore) { Val_Id_e = RPL_ONLY_W_CNF_PNRS_E; } else {\
if (pMib->Storage == &MIB_StaticDataInitStore) { Val_Id_e = STATIC_DATA_INIT_E; } else {\
if (pMib->Storage == &MIB_LogFlagStore) { Val_Id_e = LOG_FLAG_E; } else {\
if (pMib->Storage == &MIB_LogFileNameStore) { Val_Id_e = LOG_FILE_NAME_E; } else {\
if (pMib->Storage == &MIB_BackupDirPathStore) { Val_Id_e = BACKUP_DIR_PATH_E; } else {\
if (pMib->Storage == &MIB_DoBackupOnTermStore) { Val_Id_e = DO_BACKUP_ON_TERM_E; } else {\
if (pMib->Storage == &MIB_MigrateOnStore) { Val_Id_e = MIGRATE_ON_E; } else {\
}}}}}}}}}}}}}}
//
// Finds the enumerator corresponding to the pull group's parameter
//
#define PULL_ID_M(pMib, Val_Id_e) { \
if (pMib->Storage == &MIB_CommRetryCountStore) { Val_Id_e = COMM_RETRY_E; }else{\
if (pMib->Storage == &MIB_PullInitTimeStore) { Val_Id_e = PULL_INIT_TIME_E;} else{\
}}}
//
// Finds the enumerator corresponding to the push group's parameter
//
#define PUSH_ID_M(pMib, Val_Id_e) { \
if (pMib->Storage == &MIB_RplOnAddChgStore) { Val_Id_e = RPL_ON_ADD_CHG_E;} else{\
if (pMib->Storage == &MIB_PushInitTimeStore) { Val_Id_e = PUSH_INIT_TIME_E;}else{ \
}}}
STATIC
UINT
HandleCmd(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
ExecuteCmd(
IN PMIB_ENTRY pMibPtr
);
STATIC
UINT
MIB_RWReg(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
PullPnrs(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
PushPnrs(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
MIB_Table(
IN DWORD Index,
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
MIB_PullTable(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
MIB_PushTable(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
MIB_DFTable(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
MIB_DRTable(
IN UINT Action,
IN PMIB_ENTRY pMibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
WriteDFValue(
IN RFC1157VarBind *pVarBind,
PDATAFILE_INFO_T pDFKey,
DWORD Index
);
STATIC
UINT
MIB_leaf_func(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
);
STATIC
UINT
MIB_Stat(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
);
//
// MIB definiton
//
MIB_ENTRY Mib[] = {
//parameters
{ { OID_SIZEOF(MIB_Parameters), MIB_Parameters },
NULL, ASN_RFC1155_OPAQUE,
MIB_NOACCESS, NULL, &Mib[1] },
{ { OID_SIZEOF(MIB_WinsStartTime), MIB_WinsStartTime },
&MIB_WinsStartTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[2] },
{ { OID_SIZEOF(MIB_LastPScvTime), MIB_LastPScvTime },
&MIB_LastPScvTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[3] },
{ { OID_SIZEOF(MIB_LastATScvTime), MIB_LastATScvTime },
&MIB_LastATScvTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[4] },
{ { OID_SIZEOF(MIB_LastTombScvTime), MIB_LastTombScvTime },
&MIB_LastTombScvTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[5] },
{ { OID_SIZEOF(MIB_LastVerifyScvTime), MIB_LastVerifyScvTime },
&MIB_LastVerifyScvTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[6] },
{ { OID_SIZEOF(MIB_LastPRplTime), MIB_LastPRplTime },
&MIB_LastPRplTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[7] },
{ { OID_SIZEOF(MIB_LastATRplTime), MIB_LastATRplTime },
&MIB_LastATRplTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[8] },
{ { OID_SIZEOF(MIB_LastNTRplTime), MIB_LastNTRplTime },
&MIB_LastNTRplTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[9] },
{ { OID_SIZEOF(MIB_LastACTRplTime), MIB_LastACTRplTime },
&MIB_LastACTRplTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[10] },
{ { OID_SIZEOF(MIB_LastInitDbTime), MIB_LastInitDbTime },
&MIB_LastInitDbTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[11] },
{ { OID_SIZEOF(MIB_LastCounterResetTime), MIB_LastCounterResetTime },
&MIB_LastCounterResetTimeStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READ, MIB_Stat, &Mib[12] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfReg), MIB_WinsTotalNoOfReg },
&MIB_WinsTotalNoOfRegStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[13] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfQueries), MIB_WinsTotalNoOfQueries },
&MIB_WinsTotalNoOfQueriesStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[14] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfRel), MIB_WinsTotalNoOfRel },
&MIB_WinsTotalNoOfRelStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[15] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfSuccRel), MIB_WinsTotalNoOfSuccRel },
&MIB_WinsTotalNoOfSuccRelStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[16] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfFailRel), MIB_WinsTotalNoOfFailRel },
&MIB_WinsTotalNoOfFailRelStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[17] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfSuccQueries),
MIB_WinsTotalNoOfSuccQueries },
&MIB_WinsTotalNoOfSuccQueriesStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[18] },
{ { OID_SIZEOF(MIB_WinsTotalNoOfFailQueries),
MIB_WinsTotalNoOfFailQueries },
&MIB_WinsTotalNoOfFailQueriesStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READ, MIB_Stat, &Mib[19] },
{ { OID_SIZEOF(MIB_RefreshInterval), MIB_RefreshInterval },
&MIB_RefreshIntervalStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[20] },
{ { OID_SIZEOF(MIB_TombstoneInterval), MIB_TombstoneInterval },
&MIB_TombstoneIntervalStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[21] },
{ { OID_SIZEOF(MIB_TombstoneTimeout), MIB_TombstoneTimeout },
&MIB_TombstoneTimeoutStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[22] },
{ { OID_SIZEOF(MIB_VerifyInterval), MIB_VerifyInterval },
&MIB_VerifyIntervalStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[23] },
{ { OID_SIZEOF(MIB_VersCounterStartVal_LowWord),
MIB_VersCounterStartVal_LowWord },
&MIB_VersCounterStartVal_LowWordStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[24] },
{ { OID_SIZEOF(MIB_VersCounterStartVal_HighWord),
MIB_VersCounterStartVal_HighWord },
&MIB_VersCounterStartVal_HighWordStore, ASN_RFC1155_COUNTER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[25] },
{ { OID_SIZEOF(MIB_RplOnlyWCnfPnrs), MIB_RplOnlyWCnfPnrs },
&MIB_RplOnlyWCnfPnrsStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[26] },
{ { OID_SIZEOF(MIB_StaticDataInit), MIB_StaticDataInit },
&MIB_StaticDataInitStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[27] },
{ { OID_SIZEOF(MIB_LogFlag), MIB_LogFlag },
&MIB_LogFlagStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[28] },
{ { OID_SIZEOF(MIB_LogFileName), MIB_LogFileName },
&MIB_LogFileNameStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[29] },
{ { OID_SIZEOF(MIB_BackupDirPath), MIB_BackupDirPath },
&MIB_BackupDirPathStore, ASN_RFC1213_DISPSTRING,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[30] },
{ { OID_SIZEOF(MIB_DoBackupOnTerm), MIB_DoBackupOnTerm },
&MIB_DoBackupOnTermStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[31] },
{ { OID_SIZEOF(MIB_MigrateOn), MIB_MigrateOn },
&MIB_MigrateOnStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[32] },
//
// Pull
//
{ { OID_SIZEOF(MIB_Pull), MIB_Pull },
NULL, ASN_RFC1155_OPAQUE,
MIB_NOACCESS, NULL, &Mib[33] },
{ { OID_SIZEOF(MIB_PullInitTime), MIB_PullInitTime },
&MIB_PullInitTimeStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[34] },
{ { OID_SIZEOF(MIB_CommRetryCount), MIB_CommRetryCount },
&MIB_CommRetryCountStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[35] },
{ { OID_SIZEOF(MIB_PullPnrTable), MIB_PullPnrTable },
NULL, ASN_RFC1155_OPAQUE,
MIB_ACCESS_READWRITE, NULL, &Mib[36] },
{ { OID_SIZEOF(MIB_PullPnrTableEntry), MIB_PullPnrTableEntry },
NULL, ASN_SEQUENCE,
MIB_ACCESS_READWRITE, MIB_PullTable, &Mib[37] },
//
// Push
//
{ { OID_SIZEOF(MIB_Push), MIB_Push },
NULL, ASN_RFC1155_OPAQUE,
MIB_NOACCESS, NULL, &Mib[38] },
{ { OID_SIZEOF(MIB_PushInitTime), MIB_PushInitTime },
&MIB_PushInitTimeStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[39] },
{ { OID_SIZEOF(MIB_RplOnAddChg),
MIB_RplOnAddChg },
&MIB_RplOnAddChgStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, MIB_RWReg, &Mib[40] },
{ { OID_SIZEOF(MIB_PushPnrTable), MIB_PushPnrTable },
NULL, ASN_RFC1155_OPAQUE,
MIB_ACCESS_READWRITE, NULL, &Mib[41] },
{ { OID_SIZEOF(MIB_PushPnrTableEntry), MIB_PushPnrTableEntry },
NULL, ASN_SEQUENCE,
MIB_ACCESS_READWRITE, MIB_PushTable, &Mib[42] },
//
// Datafiles
//
{ { OID_SIZEOF(MIB_Datafiles), MIB_Datafiles },
NULL, ASN_RFC1155_OPAQUE,
MIB_NOACCESS, NULL, &Mib[43] },
{ { OID_SIZEOF(MIB_DatafilesTable), MIB_DatafilesTable },
NULL, ASN_RFC1155_OPAQUE,
MIB_ACCESS_READWRITE, NULL, &Mib[44] },
{ { OID_SIZEOF(MIB_DatafilesTableEntry), MIB_DatafilesTableEntry },
NULL, ASN_SEQUENCE,
MIB_ACCESS_READWRITE, MIB_DFTable, &Mib[45] },
//
// Cmds
//
{ { OID_SIZEOF(MIB_Cmd), MIB_Cmd },
NULL, ASN_RFC1155_OPAQUE,
MIB_NOACCESS, NULL, &Mib[46] },
{ { OID_SIZEOF(MIB_PullTrigger), MIB_PullTrigger },
&MIB_PullTriggerStore, ASN_RFC1155_IPADDRESS,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[47] },
{ { OID_SIZEOF(MIB_PushTrigger), MIB_PushTrigger },
&MIB_PushTriggerStore, ASN_RFC1155_IPADDRESS,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[48] },
// NOTE: The following command was changed from READWRITE
// to READ only due to security reason.
// Anyone with access to SNMP agent, could delete
// the wins database with this sigle command.
{ { OID_SIZEOF(MIB_DeleteWins), MIB_DeleteWins },
&MIB_DeleteWinsStore, ASN_RFC1155_IPADDRESS,
MIB_ACCESS_READ, HandleCmd, &Mib[49] },
{ { OID_SIZEOF(MIB_DoScavenging), MIB_DoScavenging },
&MIB_DoScavengingStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[50] },
{ { OID_SIZEOF(MIB_DoStaticInit), MIB_DoStaticInit },
&MIB_DoStaticInitStore, ASN_OCTETSTRING,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[51] },
{ { OID_SIZEOF(MIB_NoOfWrkThds), MIB_NoOfWrkThds },
&MIB_NoOfWrkThdsStore, ASN_INTEGER,
MIB_ACCESS_READ, HandleCmd, &Mib[52] },
{ { OID_SIZEOF(MIB_PriorityClass), MIB_PriorityClass},
&MIB_PriorityClassStore, ASN_INTEGER,
MIB_ACCESS_READ, HandleCmd, &Mib[53] },
{ { OID_SIZEOF(MIB_ResetCounters), MIB_ResetCounters},
&MIB_ResetCountersStore, ASN_INTEGER,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[54] },
{ { OID_SIZEOF(MIB_DeleteDbRecs), MIB_DeleteDbRecs},
&MIB_DeleteDbRecsStore, ASN_RFC1155_IPADDRESS,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[55] },
{ { OID_SIZEOF(MIB_GetDbRecs), MIB_GetDbRecs},
&MIB_GetDbRecsStore, ASN_RFC1155_IPADDRESS,
MIB_ACCESS_READWRITE, HandleCmd, &Mib[56] },
{ { OID_SIZEOF(MIB_DbRecsTable), MIB_DbRecsTable },
NULL, ASN_RFC1155_OPAQUE,
MIB_ACCESS_READWRITE, NULL, &Mib[57] },
{ { OID_SIZEOF(MIB_DbRecsTableEntry), MIB_DbRecsTableEntry },
NULL, ASN_SEQUENCE,
MIB_ACCESS_READWRITE, MIB_DRTable, &Mib[58] },
{ { OID_SIZEOF(MIB_MaxVersNo_LowWord), MIB_MaxVersNo_LowWord },
&MIB_MaxVersNo_LowWordStore, ASN_INTEGER,
MIB_ACCESS_READ, HandleCmd, &Mib[59] },
{ { OID_SIZEOF(MIB_MaxVersNo_HighWord), MIB_MaxVersNo_HighWord },
&MIB_MaxVersNo_HighWordStore, ASN_INTEGER,
MIB_ACCESS_READ, HandleCmd, NULL }
};
//
// defines pertaining to tables
//
#define PNR_OIDLEN (MIB_PREFIX_LEN + OID_SIZEOF(MIB_PullPnrTableEntry))
#define PULLPNR_OIDLEN PNR_OIDLEN
#define PUSHPNR_OIDLEN PNR_OIDLEN
#define DR_OIDLEN (MIB_PREFIX_LEN + OID_SIZEOF(MIB_DbRecsTableEntry))
#define DF_OIDLEN (MIB_PREFIX_LEN + OID_SIZEOF(MIB_DatafilesTableEntry))
#define PULL_TABLE_INDEX 0
#define PUSH_TABLE_INDEX 1
#define DF_TABLE_INDEX 2
#define DR_TABLE_INDEX 3
#define NUM_TABLES sizeof(Tables)/sizeof(TAB_INFO_T)
UINT MIB_num_variables = sizeof Mib / sizeof( MIB_ENTRY );
//
// table structure containing the functions to invoke for different actions
// on the table
//
typedef struct _TAB_INFO_T {
UINT (*ti_get)(
RFC1157VarBind *VarBind,
DWORD NoOfKeys,
LPVOID pKey
);
UINT (*ti_getf)(
RFC1157VarBind *VarBind,
PMIB_ENTRY pMibEntry,
KEY_TYPE_E KeyType_e
);
UINT (*ti_getn)(
RFC1157VarBind *VarBind,
PMIB_ENTRY pMibEntry,
KEY_TYPE_E KeyType_e
);
UINT (*ti_set)(
RFC1157VarBind *VarBind
);
PMIB_ENTRY pMibPtr;
} TAB_INFO_T, *PTAB_INFO_T;
STATIC
UINT
WriteReg(
PMIB_ENTRY pMib
);
STATIC
UINT
ReadReg(
PMIB_ENTRY pMib
);
STATIC
UINT
SetVal(
PVARINFO_T pVarInfo
);
STATIC
UINT
GetVal(
PVARINFO_T pVarInfo
);
STATIC
UINT
OpenKey(
KEY_TYPE_E Key_e,
LPBYTE pKeyStr,
HKEY *ptrNewKey,
HKEY *pRootKey,
BOOL fCreateAllowed
);
STATIC
UINT
OpenReqKey(
PMIB_ENTRY pMib,
PVAL_ID_E pVal_Id_e,
BOOL fCreateAllowed
);
STATIC
UINT
CloseReqKey(
VOID
);
STATIC
UINT
GetKeyInfo(
IN HKEY Key,
OUT LPDWORD pNoOfSubKeys,
OUT LPDWORD pNoOfVals
);
STATIC
UINT
PnrGetNext(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
PullGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumKeys,
IN LPVOID pAddKey
);
STATIC
UINT
PushGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumKeys,
IN LPVOID pAddKey
);
STATIC
UINT
PnrGetFirst(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
PullSet(
IN RFC1157VarBind *VarBind
);
STATIC
UINT
PushSet(
IN RFC1157VarBind *VarBind
);
STATIC
UINT
PnrMatch(
IN RFC1157VarBind *VarBind,
DWORD NoOfKeys,
IN PADD_KEY_T pAddKey,
IN LPDWORD pIndex,
IN LPDWORD pField,
IN KEY_TYPE_E KeyType_e,
IN UINT PduAction,
IN LPBOOL pfFirst
);
extern
UINT
PnrFindNext(
INT AddKeyNo,
DWORD NumAddKeys,
PADD_KEY_T pAddKey
);
STATIC
UINT
EnumAddKeys(
KEY_TYPE_E KeyType_e,
PADD_KEY_T *ppAddKey,
LPDWORD pNumAddKeys
);
STATIC
UINT
EnumDataFileKeys(
PDATAFILE_INFO_T *ppDFValues,
LPDWORD pNumDFValues
);
STATIC
UINT
DFSet(
IN RFC1157VarBind *VarBind
);
STATIC
UINT
DFGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumValues,
IN LPVOID pKey
);
STATIC
UINT
DFGetFirst(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
DFGetNext(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
DWORD
PopulateDRCache(
VOID
);
STATIC
UINT
DRGetNext(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
DRMatch(
IN RFC1157VarBind *VarBind,
IN PWINSINTF_RECORD_ACTION_T *ppRow,
IN LPDWORD pIndex,
IN LPDWORD pField,
IN UINT PduAction,
OUT LPBOOL pfFirst
);
STATIC
int
__cdecl
CompareIndexes(
const VOID *pKey1,
const VOID *pKey2
);
STATIC
int
__cdecl
CompareNames(
const VOID *pKey1,
const VOID *pKey2
);
// NOTE:
//
// Info passed for 2nd and 3rd param is different from other table's GET
// functions
//
STATIC
UINT
DRGet(
IN RFC1157VarBind *VarBind,
IN DWORD FieldParam,
IN LPVOID pRowParam
);
STATIC
UINT
DRGetFirst(
IN RFC1157VarBind *VarBind,
IN PMIB_ENTRY pMibPtr,
IN KEY_TYPE_E KeyType_e
);
STATIC
UINT
DRSet(
IN RFC1157VarBind *VarBind
);
STATIC
UINT
WriteKeyNValues(
KEY_TYPE_E KeyType_e,
PADD_KEY_T pAddKey,
DWORD FieldNo
);
STATIC
VOID
GetSpTimeData(
HKEY SubKey,
PADD_KEY_T pAddKey
);
STATIC
int
__cdecl
CompareAdd(
const VOID *pKey1,
const VOID *pKey2
);
STATIC
UINT
GetNextVar(
IN RFC1157VarBind *pVarBind,
IN PMIB_ENTRY pMibPtr
);
TAB_INFO_T Tables[] = {
{
PullGet,
PnrGetFirst,
PnrGetNext,
PullSet,
&Mib[36]
},
{
PushGet,
PnrGetFirst,
PnrGetNext,
PushSet,
&Mib[41]
},
{
DFGet,
DFGetFirst,
DFGetNext,
DFSet,
&Mib[44]
},
{
DRGet,
DRGetFirst,
DRGetNext,
DRSet,
&Mib[57]
}
};
UINT
ResolveVarBind(
IN OUT RFC1157VarBind *VarBind, // Variable Binding to resolve
IN UINT PduAction // Action specified in PDU
)
//
// ResolveVarBind
// Resolves a single variable binding. Modifies the variable on a GET
// or a GET-NEXT.
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
{
MIB_ENTRY *MibPtr;
AsnObjectIdentifier TempOid;
int CompResult;
UINT I;
UINT nResult;
DWORD TableIndex;
BOOL fTableMatch = FALSE;
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Entering ResolveVarBind.\n"));
// initialize MibPtr to NULL. When this becomes not null, it means we found a match (table or scalar)
MibPtr = NULL;
//
// Check the Tables array
//
// See if the prefix of the variable matches the prefix of
// any of the tables
//
for (TableIndex = 0; TableIndex < NUM_TABLES; TableIndex++)
{
//
// Construct OID with complete prefix for comparison purposes
//
SNMP_oidcpy( &TempOid, &MIB_OidPrefix );
if (TempOid.ids == NULL)
{
nResult = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
SNMP_oidappend( &TempOid, &Tables[TableIndex].pMibPtr->Oid );
//
// is there a match with the prefix oid of a table entry
//
if (
SnmpUtilOidNCmp(
&VarBind->name,
&TempOid,
MIB_PREFIX_LEN +
Tables[TableIndex].pMibPtr->Oid.idLength
) == 0
)
{
//
// the prefix string of the var. matched the oid
// of a table.
//
MibPtr = Tables[TableIndex].pMibPtr;
fTableMatch = TRUE;
break;
}
// Free OID memory before checking with another table entry
SNMP_oidfree( &TempOid );
}
//
// There was an exact match with a table entry's prefix.
//
if ( fTableMatch)
{
if (
(SnmpUtilOidCmp(
&VarBind->name,
&TempOid
) == 0)
)
{
//
// The oid specified is a prefix of a table entry. if the operation
// is not GETNEXT, return NOSUCHNAME
//
if (PduAction != MIB_GETNEXT)
{
SNMP_oidfree( &TempOid );
nResult = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
else
{
UINT TableEntryIds[1];
AsnObjectIdentifier TableEntryOid = {
OID_SIZEOF(TableEntryIds), TableEntryIds };
//
// Replace var bind name with new name
//
//
// A sequence item oid always starts with a field no.
// The first item has a field no of 1.
//
TableEntryIds[0] = 1;
SNMP_oidappend( &VarBind->name, &TableEntryOid);
//
// Get the first entry in the table
//
PduAction = MIB_GETFIRST;
}
}
SNMP_oidfree( &TempOid );
//
// if there was no exact match with a prefix entry, then we
// don't touch the PduAction value specified.
//
}
else
{
//
// There was no match with any table entry. Let us see if there is
// a match with a group entry, a table, or a leaf variable
//
//
// Search for var bind name in the MIB
//
I = 0;
while ( MibPtr == NULL && I < MIB_num_variables )
{
//
// Construct OID with complete prefix for comparison purposes
//
SNMP_oidcpy( &TempOid, &MIB_OidPrefix );
SNMP_oidappend( &TempOid, &Mib[I].Oid );
//
//Check for OID in MIB - On a GET-NEXT the OID does not have to exactly
// match a variable in the MIB, it must only fall under the MIB root.
//
CompResult = SNMP_oidcmp( &VarBind->name, &TempOid );
//
// If CompResult is negative, the only valid operation is GET_NEXT
//
if ( CompResult < 0)
{
//
// This could be the oid of a leaf (without a 0)
// or it could be an invalid oid (in between two valid oids)
// The next oid might be that of a group or a table or table
// entry. In that case, we do not change the PduAction
//
if (PduAction == MIB_GETNEXT)
{
MibPtr = &Mib[I];
SNMP_oidfree( &VarBind->name );
SNMP_oidcpy( &VarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &VarBind->name, &MibPtr->Oid );
if (MibPtr->Type != ASN_RFC1155_OPAQUE)
{
PduAction = (MibPtr->Type == ASN_SEQUENCE)? MIB_GETFIRST : MIB_GET;
}
}
else
{
nResult = SNMP_ERRORSTATUS_NOSUCHNAME;
SNMP_oidfree( &TempOid );
goto Exit;
}
SNMP_oidfree( &TempOid );
break;
}
else
{
//
// An exact match was found ( a group, table, or leaf).
//
if ( CompResult == 0)
{
MibPtr = &Mib[I];
}
}
//
// Free OID memory before checking another variable
//
SNMP_oidfree( &TempOid );
I++;
} // while
} // end of else
//
// if there was a match
//
if (MibPtr != NULL)
{
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Found MibPtr.\n"));
//
// the function will be NULL only if the match was with a group
// or a sequence (table). If the match was with a table entry
// (entire VarBind string match or partial string match), we
// function would be a table function
//
if (MibPtr->MibFunc == NULL)
{
if(PduAction != MIB_GETNEXT)
{
nResult = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
else
{
//
// Get the next variable which allows access
//
nResult = GetNextVar(VarBind, MibPtr);
goto Exit;
}
}
}
else
{
nResult = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Diving in OID handler.\n"));
//
// Call function to process request. Each MIB entry has a function pointer
// that knows how to process its MIB variable.
//
nResult = (*MibPtr->MibFunc)( PduAction, MibPtr, VarBind );
Exit:
return nResult;
} // ResolveVarBind
//
// MIB_leaf_func
// Performs generic actions on LEAF variables in the MIB.
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
UINT MIB_leaf_func(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
UINT ErrStat;
switch ( Action )
{
case MIB_GETNEXT:
//
// If there is no GET-NEXT pointer, this is the end of this MIB
//
if ( MibPtr->MibNext == NULL )
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
ErrStat = GetNextVar(VarBind, MibPtr);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
goto Exit;
}
break;
case MIB_GETFIRST: // fall through
case MIB_GET:
// Make sure that this variable's ACCESS is GET'able
if ( MibPtr->Access != MIB_ACCESS_READ &&
MibPtr->Access != MIB_ACCESS_READWRITE )
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
// Setup varbind's return value
VarBind->value.asnType = MibPtr->Type;
switch ( VarBind->value.asnType )
{
case ASN_RFC1155_COUNTER:
VarBind->value.asnValue.number = *(AsnCounter *)(MibPtr->Storage);
break;
case ASN_RFC1155_GAUGE:
case ASN_INTEGER:
VarBind->value.asnValue.number = *(AsnInteger *)(MibPtr->Storage);
break;
case ASN_RFC1155_IPADDRESS:
// continue as for ASN_OCTETSTRING
case ASN_OCTETSTRING:
if (VarBind->value.asnType == ASN_RFC1155_IPADDRESS)
{
VarBind->value.asnValue.string.length = 4;
}
else
{
VarBind->value.asnValue.string.length =
strlen( (LPSTR)MibPtr->Storage );
}
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(char))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)MibPtr->Storage,
VarBind->value.asnValue.string.length );
VarBind->value.asnValue.string.dynamic = TRUE;
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
break;
case MIB_SET:
// Make sure that this variable's ACCESS is SET'able
if ( MibPtr->Access != MIB_ACCESS_READWRITE &&
MibPtr->Access != MIB_ACCESS_WRITE )
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
// Check for proper type before setting
if ( MibPtr->Type != VarBind->value.asnType )
{
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
goto Exit;
}
// Save value in MIB
switch ( VarBind->value.asnType )
{
case ASN_RFC1155_COUNTER:
*(AsnCounter *)(MibPtr->Storage) = VarBind->value.asnValue.number;
break;
case ASN_RFC1155_GAUGE:
case ASN_INTEGER:
*(AsnInteger *)(MibPtr->Storage) = VarBind->value.asnValue.number;
break;
case ASN_RFC1155_IPADDRESS:
if (MibPtr->Storage == &MIB_PullTriggerStore ||
MibPtr->Storage == &MIB_PushTriggerStore ||
MibPtr->Storage == &MIB_DeleteDbRecsStore ||
MibPtr->Storage == &MIB_DeleteWinsStore)
{
int backupSize = (MibPtr->Storage == &MIB_PullTriggerStore) ?
sizeof(MIB_PullTriggerStore)/2 :
sizeof(MIB_PushTriggerStore)/2 ;
// those variables are ASN_RFC1155_IPADDRESS
// their old values have to be stored as the WinsTrigger() might fail
// in which case the old values will be restored
// each of these variables has 10 octets, the payload being of 5 octets.
// the last 5 = for backup
memcpy( (LPSTR)MibPtr->Storage + backupSize, (LPSTR)MibPtr->Storage, backupSize);
}
case ASN_OCTETSTRING:
// The storage must be adequate to contain the new string
// including a NULL terminator.
memcpy( (LPSTR)MibPtr->Storage,
VarBind->value.asnValue.string.stream,
VarBind->value.asnValue.string.length );
((LPSTR)MibPtr->Storage)[VarBind->value.asnValue.string.length] =
'\0';
#if 0
if ( VarBind->value.asnValue.string.dynamic)
{
SNMP_free( VarBind->value.asnValue.string.stream);
}
#endif
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
} // switch
// Signal no error occurred
ErrStat = SNMP_ERRORSTATUS_NOERROR;
Exit:
return ErrStat;
} // MIB_leaf_func
#define TMST(x) sResults.WinsStat.TimeStamps.x.wHour,\
sResults.WinsStat.TimeStamps.x.wMinute,\
sResults.WinsStat.TimeStamps.x.wSecond,\
sResults.WinsStat.TimeStamps.x.wMonth,\
sResults.WinsStat.TimeStamps.x.wDay,\
sResults.WinsStat.TimeStamps.x.wYear
#define PRINTTIME(Var, x) sprintf(Var, "%02u:%02u:%02u on %02u:%02u:%04u.\n", TMST(x))
static WINSINTF_RESULTS_T sResults;
//
// MIB_Stat
// Performs specific actions on the different MIB variable
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
UINT MIB_Stat(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
//WINSINTF_RESULTS_T Results;
DWORD Status;
UINT ErrStat;
handle_t BindHdl;
switch ( Action )
{
case MIB_SET:
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
case MIB_GETNEXT:
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
case MIB_GETFIRST:
#if 0
//
// If it is an OPAQUE type (i.e. aggregate)
//
if (MibPtr->Type == ASN_RFC1155_OPAQUE)
{
ErrStat = MIB_leaf_func( MIB_GETNEXT, MibPtr, VarBind );
break;
}
#endif
//
// fall through
//
case MIB_GET:
if (!fWinsMibWinsStatusStatCalled)
{
//
// Call the WinsStatus function to get the statistics
//
BindHdl = WinsBind(&sBindData);
sResults.WinsStat.NoOfPnrs = 0;
sResults.WinsStat.pRplPnrs = NULL;
if ((Status = WinsStatus(BindHdl, WINSINTF_E_STAT, &sResults)) !=
WINSINTF_SUCCESS)
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error from WinsStatus = (%d).\n",
Status
));
WinsFreeMem(sResults.WinsStat.pRplPnrs);
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
else
{
fWinsMibWinsStatusStatCalled = TRUE;
}
WinsFreeMem(sResults.WinsStat.pRplPnrs);
WinsUnbind(&sBindData, BindHdl);
}
if (MibPtr->Storage == &MIB_WinsStartTimeStore)
{
PRINTTIME(MIB_WinsStartTimeStore, WinsStartTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastPScvTimeStore)
{
PRINTTIME(MIB_LastPScvTimeStore, LastPScvTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastATScvTimeStore)
{
PRINTTIME(MIB_LastATScvTimeStore, LastATScvTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastTombScvTimeStore)
{
PRINTTIME(MIB_LastTombScvTimeStore, LastTombScvTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastVerifyScvTimeStore)
{
PRINTTIME(MIB_LastVerifyScvTimeStore, LastVerifyScvTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastPRplTimeStore)
{
PRINTTIME(MIB_LastPRplTimeStore, LastPRplTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastATRplTimeStore)
{
PRINTTIME(MIB_LastATRplTimeStore, LastATRplTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastNTRplTimeStore)
{
PRINTTIME(MIB_LastNTRplTimeStore, LastNTRplTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastACTRplTimeStore)
{
PRINTTIME(MIB_LastACTRplTimeStore, LastACTRplTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastInitDbTimeStore)
{
PRINTTIME(MIB_LastInitDbTimeStore, LastInitDbTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_LastCounterResetTimeStore)
{
PRINTTIME(MIB_LastCounterResetTimeStore, CounterResetTime);
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfRegStore)
{
MIB_WinsTotalNoOfRegStore =
sResults.WinsStat.Counters.NoOfUniqueReg +
sResults.WinsStat.Counters.NoOfGroupReg;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfQueriesStore)
{
MIB_WinsTotalNoOfQueriesStore =
sResults.WinsStat.Counters.NoOfQueries;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfRelStore)
{
MIB_WinsTotalNoOfRelStore = sResults.WinsStat.Counters.NoOfRel;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfSuccRelStore)
{
MIB_WinsTotalNoOfSuccRelStore =
sResults.WinsStat.Counters.NoOfSuccRel;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfFailRelStore)
{
MIB_WinsTotalNoOfFailRelStore =
sResults.WinsStat.Counters.NoOfFailRel;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfSuccQueriesStore)
{
MIB_WinsTotalNoOfSuccQueriesStore =
sResults.WinsStat.Counters.NoOfSuccQueries;
goto LEAF1;
}
if (MibPtr->Storage == &MIB_WinsTotalNoOfFailQueriesStore)
{
MIB_WinsTotalNoOfFailQueriesStore =
sResults.WinsStat.Counters.NoOfFailQueries;
// goto LEAF1;
}
LEAF1:
// Call the more generic function to perform the action
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
} // switch
Exit:
return ErrStat;
} // MIB_Stat
//
// MIB_RWReg
// Performs specific actions on the different MIB variable
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
UINT MIB_RWReg(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
WINSINTF_RESULTS_T Results;
DWORD Status;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
handle_t BindHdl;
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Entering MIB_RWReg.\n"));
switch ( Action )
{
case MIB_SET:
if (MIB_leaf_func( Action, MibPtr, VarBind )
== SNMP_ERRORSTATUS_NOERROR)
{
ErrStat = WriteReg(MibPtr);
}
break;
case MIB_GETFIRST:
#if 0
//
// If it is an OPAQUE type (i.e. aggregate)
//
if (MibPtr->Type == ASN_RFC1155_OPAQUE)
{
ErrStat = MIB_leaf_func( MIB_GETNEXT, MibPtr, VarBind );
break;
}
#endif
//
// fall through
//
case MIB_GET:
//
// Call the WinsStatus function to get the statistics
//
if (
(MibPtr->Storage == &MIB_RefreshIntervalStore)
||
(MibPtr->Storage == &MIB_TombstoneIntervalStore)
||
(MibPtr->Storage == &MIB_TombstoneTimeoutStore)
||
(MibPtr->Storage == &MIB_VerifyIntervalStore)
)
{
BindHdl = WinsBind(&sBindData);
Results.WinsStat.NoOfPnrs = 0;
Results.WinsStat.pRplPnrs = NULL;
if ((Status = WinsStatus(BindHdl, WINSINTF_E_CONFIG, &Results))
== WINSINTF_SUCCESS)
{
MIB_RefreshIntervalStore = Results.RefreshInterval;
MIB_TombstoneIntervalStore = Results.TombstoneInterval;
MIB_TombstoneTimeoutStore = Results.TombstoneTimeout;
MIB_VerifyIntervalStore = Results.VerifyInterval;
}
else
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error from WinsStatus = (%d).\n",
Status
));
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
WinsUnbind(&sBindData, BindHdl);
}
else
{
//
// If a value could not be read
// then the storage for the mib variable would have been
// initialized to 0.
//
ErrStat = ReadReg(MibPtr);
}
//
// fall through
//
case MIB_GETNEXT:
//
// Call the more generic function to perform the action
//
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
} // switch
Exit:
return ErrStat;
} // MIB_RWReg
UINT
OpenReqKey(
MIB_ENTRY *pMib,
VAL_ID_E *pVal_Id_e,
BOOL fCreateAllowed
)
/*++
Routine Description:
The function opens the required keys for the parameter indicated
by the structure pointed to by pMib
Arguments:
Externals Used:
None
Return Value:
Success status codes --
Error status codes --
Error Handling:
Called by:
Side Effects:
Comments:
None
--*/
{
UINT Status = SNMP_ERRORSTATUS_GENERR;
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Entering OpenReqKey.\n"));
//
// if it is a parameter value, open the parameters key
//
if (PARAMETERS_VAL_M(pMib))
{
Status = OpenKey(PARAMETERS_E_KEY, NULL, NULL, NULL, fCreateAllowed);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
// sfParametersKeyOpen = TRUE;
PARAMETERS_ID_M(pMib, *pVal_Id_e);
}
}
else
{
//
// if it is a Pull key value, open the partner and
// pull keys
//
if (PULL_VAL_M(pMib))
{
Status = OpenKey(PARTNERS_E_KEY, NULL, NULL, NULL, fCreateAllowed);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
//sfPartnersKeyOpen = TRUE;
Status = OpenKey(PULL_E_KEY, NULL, NULL, NULL, fCreateAllowed);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
PULL_ID_M(pMib, *pVal_Id_e);
}
}
}
else
{
//
// if it is a Push key value, open the partner and
// pull keys
//
if (PUSH_VAL_M(pMib))
{
Status = OpenKey(PARTNERS_E_KEY, NULL, NULL, NULL, fCreateAllowed);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
sfPartnersKeyOpen = TRUE;
Status = OpenKey(PUSH_E_KEY, NULL, NULL, NULL, fCreateAllowed);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
PUSH_ID_M(pMib, *pVal_Id_e);
}
}
}
}
}
return(Status);
}
UINT
CloseReqKey(
VOID
)
/*++
Routine Description:
Arguments:
Externals Used:
None
Return Value:
Success status codes --
Error status codes --
Error Handling:
Called by:
Side Effects:
Comments:
None
--*/
{
UINT Status = SNMP_ERRORSTATUS_NOERROR;
if (sfParametersKeyOpen)
{
if (sfDatafilesKeyOpen)
{
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sDatafilesKey 0x%08lx (fKeyOpen=TRUE).\n",
sDatafilesKey
));
RegCloseKey(sDatafilesKey);
sfDatafilesKeyOpen = FALSE;
}
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sParametersKey 0x%08lx (fKeyOpen=TRUE).\n",
sParametersKey
));
RegCloseKey(sParametersKey);
sfParametersKeyOpen = FALSE;
}
else
{
if (sfPartnersKeyOpen)
{
if (sfPullKeyOpen)
{
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sPullKey 0x%08lx (fKeyOpen=TRUE).\n",
sPullKey
));
RegCloseKey(sPullKey);
sfPullKeyOpen = FALSE;
}
else
{
if (sfPushKeyOpen)
{
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sPushKey 0x%08lx (fKeyOpen=TRUE).\n",
sPushKey
));
RegCloseKey(sPushKey);
sfPushKeyOpen = FALSE;
}
}
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sPartnersKey 0x%08lx (fKeyOpen=TRUE).\n",
sPartnersKey
));
RegCloseKey(sPartnersKey);
sfPartnersKeyOpen = FALSE;
}
}
return(Status);
}
UINT
ReadReg(
MIB_ENTRY *pMib
)
{
UINT Status = SNMP_ERRORSTATUS_NOERROR;
VAL_ID_E Val_Id_e;
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: Entering ReadReg.\n"));
Status = OpenReqKey(pMib, &Val_Id_e, FALSE);
if (Status == SNMP_ERRORSTATUS_NOERROR)
{
Status = GetVal(&VarInfo[Val_Id_e]);
}
CloseReqKey();
return(Status);
}
UINT
WriteReg(
MIB_ENTRY *pMib
)
{
UINT Status = SNMP_ERRORSTATUS_NOERROR;
VAL_ID_E Val_Id_e;
Status = OpenReqKey(pMib, &Val_Id_e, TRUE);
if (SNMP_ERRORSTATUS_NOERROR == Status) {
Status = SetVal(&VarInfo[Val_Id_e]);
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sParametersKey 0x%08lx (fKeyOpen=%s).\n",
sParametersKey, sfParametersKeyOpen ? "TRUE" : "FALSE"
));
}
CloseReqKey();
//RegCloseKey(sParametersKey);
return(Status);
}
UINT
OpenKey(
KEY_TYPE_E Key_e,
LPBYTE ptrKeyStr,
HKEY *ptrNewKey,
HKEY *pRootKey,
BOOL fCreateAllowed
)
{
LONG RetVal;
DWORD NewKeyInd;
HKEY RootKey;
LPBYTE pKeyStr;
HKEY *pNewKey;
LPBOOL pfNewKeyOpen;
if (!fWinsMibWinsKeyOpen)
{
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Creating/opening Wins key.\n",
WinsMibWinsKey
));
RetVal = RegCreateKeyEx(
HKEY_LOCAL_MACHINE, //predefined key value
_WINS_CNF_KEY, //subkey for WINS
0, //must be zero (reserved)
TEXT("Class"), //class -- may change in future
REG_OPTION_NON_VOLATILE, //non-volatile information
KEY_ALL_ACCESS, //we desire all access to the keyo
NULL, //let key have default sec. attributes
&WinsMibWinsKey, //handle to key
&NewKeyInd //is it a new key (out arg)
);
if (RetVal != ERROR_SUCCESS)
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error creating/opening Wins key 0x%08lx.\n",
GetLastError()
));
return(SNMP_ERRORSTATUS_GENERR);
}
fWinsMibWinsKeyOpen = TRUE;
}
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: WinsMibWinsKey=0x%08lx, opening %s.\n",
WinsMibWinsKey,
(Key_e == PARAMETERS_E_KEY)
? "PARAMETERS_E_KEY"
: (Key_e == PARTNERS_E_KEY)
? "PARTNERS_E_KEY"
: (Key_e == PULL_E_KEY)
? "PULL_E_KEY"
: (Key_e == PUSH_E_KEY)
? "PUSH_E_KEY"
: (Key_e == DATAFILES_E_KEY)
? "DATAFILES_E_KEY"
: "IPADD_E_KEY"
));
switch(Key_e)
{
case(PARAMETERS_E_KEY):
RootKey = WinsMibWinsKey;
pKeyStr = _WINS_PARAMETERS_KEY;
pNewKey = &sParametersKey;
pfNewKeyOpen = &sfParametersKeyOpen;
break;
case(PARTNERS_E_KEY):
RootKey = WinsMibWinsKey;
pKeyStr = _WINS_PARTNERS_KEY;
pNewKey = &sPartnersKey;
pfNewKeyOpen = &sfPartnersKeyOpen;
break;
case(PULL_E_KEY):
RootKey = sPartnersKey;
pKeyStr = _WINS_PULL_KEY;
pNewKey = &sPullKey;
pfNewKeyOpen = &sfPullKeyOpen;
break;
case(PUSH_E_KEY):
RootKey = sPartnersKey;
pKeyStr = _WINS_PUSH_KEY;
pNewKey = &sPushKey;
pfNewKeyOpen = &sfPushKeyOpen;
break;
case(DATAFILES_E_KEY):
RootKey = sParametersKey;
pKeyStr = _WINS_DATAFILES_KEY;
pNewKey = &sDatafilesKey;
pfNewKeyOpen = &sfDatafilesKeyOpen;
break;
case(IPADD_E_KEY):
RootKey = *pRootKey;
pKeyStr = ptrKeyStr;
pNewKey = ptrNewKey;
break;
default:
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error in key type.\n"
));
return(SNMP_ERRORSTATUS_GENERR);
}
if (fCreateAllowed)
{
RetVal = RegCreateKeyEx(
RootKey, //predefined key value
pKeyStr, //subkey for WINS
0, //must be zero (reserved)
TEXT("Class"), //class -- may change in future
REG_OPTION_NON_VOLATILE, //non-volatile information
KEY_ALL_ACCESS, //we desire all access to the keyo
NULL, //let key have default sec. attributes
pNewKey, //handle to key
&NewKeyInd //is it a new key (out arg)
);
}
else
{
RetVal = RegOpenKeyEx(
RootKey, //predefined key value
pKeyStr, //subkey for WINS
0, //must be zero (reserved)
KEY_READ, //we desire read access to the keyo
pNewKey //handle to key
);
}
if (RetVal != ERROR_SUCCESS)
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error creating/opening Wins/Parameters key 0x%08lx.\n",
GetLastError()
));
return(SNMP_ERRORSTATUS_GENERR);
}
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Opened %s=0x%08lx (fKeyOpen=TRUE).\n",
(Key_e == PARAMETERS_E_KEY)
? "sParametersKey"
: (Key_e == PARTNERS_E_KEY)
? "sPartnersKey"
: (Key_e == PULL_E_KEY)
? "sPullKey"
: (Key_e == PUSH_E_KEY)
? "sPushKey"
: (Key_e == DATAFILES_E_KEY)
? "sDatafilesKey"
: "ipAddKey", *pNewKey
));
if (Key_e != IPADD_E_KEY)
{
if (ptrNewKey != NULL)
{
*ptrNewKey = *pNewKey;
}
*pfNewKeyOpen = TRUE;
}
return(SNMP_ERRORSTATUS_NOERROR);
}
UINT
SetVal(
PVARINFO_T pVarInfo
)
{
UINT Status = SNMP_ERRORSTATUS_NOERROR;
LONG RetVal;
RetVal = RegSetValueEx(
*(pVarInfo->pRootKey),
pVarInfo->pName,
0, //reserved -- must be 0
pVarInfo->ValType,
pVarInfo->pStorage,
pVarInfo->ValType == REG_DWORD ?
pVarInfo->SizeOfData :
strlen(pVarInfo->pStorage)
);
if (RetVal != ERROR_SUCCESS)
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Could not set value of %s.\n",
pVarInfo->pName
));
Status = SNMP_ERRORSTATUS_GENERR;
}
return(Status);
}
UINT
GetVal(
PVARINFO_T pVarInfo
)
{
LONG RetVal;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD ValType;
DWORD Sz;
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: GetVal(%s).\n",
// pVarInfo->pName));
Sz = pVarInfo->SizeOfData;
RetVal = RegQueryValueEx(
*(pVarInfo->pRootKey),
pVarInfo->pName,
NULL,
&ValType,
pVarInfo->pStorage,
&Sz
);
// SNMPDBG ((SNMP_LOG_TRACE,
// "WINSMIB: GetVal()->%d\n",
// RetVal));
if (RetVal != ERROR_SUCCESS)
{
(VOID)RtlFillMemory(pVarInfo->pStorage, pVarInfo->SizeOfData, 0);
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
return(ErrStat);
}
#if 0
//
// PullPnrs
// Performs specific actions on the PullPnrs table
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
UINT
PullPnrs(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind,
IN PTABLE_ENTRY *TablePtr
)
{
WINSINTF_RESULTS_T Results;
DWORD Status = WINSINTF_SUCCESS;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
handle_t BindHdl;
BindHdl = WinsBind(&sBindData);
switch ( Action )
{
case MIB_SET:
break;
case MIB_GETNEXT:
case MIB_GET:
ErrStat = TableMatch(MibPtr, VarBind, TablePtr);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
//
// Call the WinsStatus function to get the statistics
//
if (
(MibPtr->Storage == &MIB_RefreshIntervalStore)
||
(MibPtr->Storage == &MIB_TombstoneIntervalStore)
||
(MibPtr->Storage == &MIB_TombstoneTimeoutStore)
||
(MibPtr->Storage == &MIB_VerifyIntervalStore)
)
{
Status = WinsStatus(WINSINTF_E_CONFIG, &Results);
if (Status == WINSINTF_SUCCESS)
{
MIB_RefreshIntervalStore = Results.RefreshInterval;
MIB_TombstoneIntervalStore = Results.TombstoneInterval;
MIB_TombstoneTimeoutStore = Results.TombstoneTimeout;
MIB_VerifyIntervalStore = Results.VerifyInterval;
}
else
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Error from WinsStatus = (%d).\n",
Status
));
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
}
else
{
if ((ErrStat = ReadReg(MibPtr)) != SNMP_ERRORSTATUS_NOERROR)
{
break;
}
}
// Call the more generic function to perform the action
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
} // switch
Exit:
WinsUnbind(&sBindData, BindHdl);
return ErrStat;
} //PullPnrs
#endif
UINT
PnrGetNext(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
DWORD OidIndex;
DWORD NumAddKeys;
INT Index;
PADD_KEY_T pAddKey = NULL;
DWORD FieldNo;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
BOOL fFirst;
//
// Read in all ip address keys. For each key, the values of its fields
// is stored in the ADD_KEY_T structure. The number of Address
// keys are stored in NumAddKeys and in the TABLE_INFO structure
//
ErrStat = EnumAddKeys(KeyType_e, &pAddKey, &NumAddKeys);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return ErrStat;
}
//
// Check if the name passed matches any in the table (i.e. table of
// of ADD_KEY_T structures. If there is a match, the address
// of the ip address key and the matching field's no. are returned
//
ErrStat = PnrMatch(VarBind, NumAddKeys, pAddKey, &Index,
&FieldNo, KeyType_e, MIB_GETNEXT, &fFirst);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
goto Exit;
// return(ErrStat);
}
//
// We were passed an oid that is less than all oids in the table. Set
// the Index to -1 so that we retrieve the first record in the table
//
if (fFirst)
{
Index = -1;
}
//
// Since the operation is GETNEXT, get the next IP address (i.e. one
// that is lexicographically bigger. If there is none, we must increment
// the field value and move back to the lexically first item in the table
// If the new field value is more than the largest supported, we call
// the MibFunc of the next MIB entry.
//
if ((Index = PnrFindNext(Index, NumAddKeys, pAddKey)) < 0)
{
//
// if we were trying to retrieve the second or subsequent record
// we must increment the field number nd get the first record in
// the table. If we were retrieving the first record, then
// we should get the next var.
//
if (!fFirst)
{
Index = PnrFindNext(-1, NumAddKeys, pAddKey);
}
else
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
return(GetNextVar(VarBind, MibPtr));
}
//
// If either there is no entry in the table or if we have
// exhausted all fields of the entry, call the function
// of the next mib entry.
//
if (
(++FieldNo > (DWORD)((KeyType_e == PULL_E_KEY)
? NO_FLDS_IN_PULLADD_KEY
: NO_FLDS_IN_PUSHADD_KEY)) || (Index < 0)
)
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
return(GetNextVar(VarBind, MibPtr));
}
}
//
// The fixed part of the objid is corect. Update the rest.
//
//
// If there is not enough space, deallocate what is currently
// there and allocate.
//
if (VarBind->name.idLength <= (PNR_OIDLEN + 4))
{
UINT TableEntryIds[5]; //field and Ip address have a length of 5
AsnObjectIdentifier TableEntryOid = {OID_SIZEOF(TableEntryIds),
TableEntryIds };
SNMP_oidfree( &VarBind->name);
SNMP_oidcpy(&VarBind->name, &MIB_OidPrefix);
SNMP_oidappend(&VarBind->name, &MibPtr->Oid);
TableEntryIds[0] = (UINT)FieldNo;
OidIndex = 1;
TableEntryIds[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 24);
TableEntryIds[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 16 & 0xFF);
TableEntryIds[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 8 & 0xFF);
TableEntryIds[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd & 0xFF);
TableEntryOid.idLength = OidIndex;
SNMP_oidappend(&VarBind->name, &TableEntryOid);
}
else
{
OidIndex = PNR_OIDLEN;
VarBind->name.ids[OidIndex++] = (UINT)FieldNo;
VarBind->name.ids[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 24);
VarBind->name.ids[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 16 & 0xFF);
VarBind->name.ids[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd >> 8 & 0xFF);
VarBind->name.ids[OidIndex++] = (UINT)((pAddKey + Index)->IpAdd & 0xFF);
VarBind->name.idLength = OidIndex;
}
//
// Get the value
//
if (KeyType_e == PULL_E_KEY)
{
ErrStat = PullGet(VarBind, NumAddKeys, pAddKey);
}
else
{
ErrStat = PushGet(VarBind, NumAddKeys, pAddKey);
}
//
// Let us free the memory that was allocated earlier. No need to
// check whether pAddKey is NULL. It just can not be otherwise we
// would have returned from this function earlier.
//
Exit:
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
return(ErrStat);
}
UINT
PullGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumKeys,
IN LPVOID pKey
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
DWORD Index;
DWORD NumAddKeys = NumKeys;
IN PADD_KEY_T pAddKey = pKey;
if (pAddKey == NULL)
{
//
// Call EnumAddresses only if we have not been invoked by PnrGetNext
//
EnumAddKeys(PULL_E_KEY, &pAddKey, &NumAddKeys);
}
ErrStat = PnrMatch(VarBind, NumAddKeys, pAddKey, &Index, &Field,
PULL_E_KEY, MIB_GET, NULL);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
goto Exit;
//return(ErrStat);
}
switch(Field)
{
case 1: //IP address itself
VarBind->value.asnType = ASN_RFC1155_IPADDRESS;
VarBind->value.asnValue.string.length = sizeof(ULONG);
if ( NULL == (VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length
)) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
VarBind->value.asnValue.string.stream[0] =
(BYTE)((pAddKey + Index)->IpAdd >> 24);
VarBind->value.asnValue.string.stream[1] =
(BYTE)(((pAddKey + Index)->IpAdd >> 16) & 0xFF);
VarBind->value.asnValue.string.stream[2] =
(BYTE)(((pAddKey + Index)->IpAdd >> 8) & 0xFF);
VarBind->value.asnValue.string.stream[3] =
(BYTE)((pAddKey + Index)->IpAdd & 0xFF );
VarBind->value.asnValue.address.dynamic = TRUE;
#if 0
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)(&((pAddKey + Index)->IpAdd)),
VarBind->value.asnValue.string.length );
*((ULONG *)VarBind->value.asnValue.address.stream)
= (ULONG)(pAddKey + Index)->IpAdd;
#endif
#if 0
VarBind->value.asnValue.string.length =
strlen( (LPSTR)((pAddKey + Index)->asIpAddress));
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(char))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)((pAddKey + Index)->asIpAddress),
VarBind->value.asnValue.string.length );
#endif
break;
case 2: // SpTime
VarBind->value.asnType = ASN_RFC1213_DISPSTRING;
if (((pAddKey + Index)->asSpTime[0]) != EOS)
{
VarBind->value.asnValue.string.length =
strlen( (LPSTR)((pAddKey + Index)->asSpTime));
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(char))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)((pAddKey + Index)->asSpTime),
VarBind->value.asnValue.string.length );
}
else
{
VarBind->value.asnValue.string.length = 0;
VarBind->value.asnValue.string.stream = NULL;
}
VarBind->value.asnValue.address.dynamic = TRUE;
break;
case 3: // TimeInterval
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)((pAddKey + Index)->
TimeInterval);
break;
case 4: //Member Precedence
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)((pAddKey + Index)->
MemberPrec);
break;
case 5: //No of successful replications
VarBind->value.asnType = ASN_RFC1155_COUNTER;
VarBind->value.asnValue.number =
(AsnCounter)((pAddKey + Index)->
NoOfRpls);
break;
case 6: //No of replication failures due to comm failures
VarBind->value.asnType = ASN_RFC1155_COUNTER;
VarBind->value.asnValue.number =
(AsnCounter)((pAddKey + Index)->
NoOfCommFails);
break;
case 7: //Low part of the highest vers. no of owned records
VarBind->value.asnType = ASN_RFC1155_COUNTER;
VarBind->value.asnValue.number =
(AsnCounter)((pAddKey + Index)->
VersNo.LowPart);
break;
case 8: //High part of the highest vers. no of owned records
VarBind->value.asnType = ASN_RFC1155_COUNTER;
VarBind->value.asnValue.number =
(AsnCounter)((pAddKey + Index)->
VersNo.HighPart);
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
Exit:
//
// if we allocated memory here, free it
//
if ((pKey == NULL) && (pAddKey != NULL))
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
}
return(ErrStat);
}
UINT
PnrMatch(
IN RFC1157VarBind *VarBind,
DWORD NoOfKeys,
IN PADD_KEY_T pAddKey,
IN LPDWORD pIndex,
IN LPDWORD pField,
IN KEY_TYPE_E KeyType_e,
IN UINT PduAction,
IN LPBOOL pfFirst
)
{
DWORD OidIndex;
DWORD Index;
DWORD AddIndex;
DWORD Add = 0;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD AddLen;
ASSERT(PduAction != MIB_SET);
if (pfFirst != NULL)
{
*pfFirst = FALSE;
}
//
// If there are no keys, return error
//
if (NoOfKeys == 0)
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
//
// fixed part of the PullPnr table entries
//
OidIndex = PNR_OIDLEN;
//
// if the field specified is more than the max. in the table entry
// barf
//
if (
(NoOfKeys == 0)
||
((*pField = VarBind->name.ids[OidIndex++]) >
(DWORD)
((KeyType_e == PULL_E_KEY) ? NO_FLDS_IN_PULLADD_KEY
: NO_FLDS_IN_PUSHADD_KEY))
)
{
if (PduAction == MIB_GETNEXT)
{
if (NoOfKeys == 0)
{
*pfFirst = TRUE;
}
else
{
*pIndex = NoOfKeys - 1;
}
}
else
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
}
goto Exit;
}
//
// get the length of key specified
//
AddLen = VarBind->name.idLength - (PNR_OIDLEN + 1);
AddIndex = OidIndex;
for (Index = 0; Index < AddLen; Index++)
{
Add = Add | (((BYTE)(VarBind->name.ids[AddIndex++])) << (24 - (Index * 8)));
}
//
// Check if the address specified matches with one of the keys
//
for (Index = 0; Index < NoOfKeys; Index++, pAddKey++)
{
if (Add == pAddKey->IpAdd)
{
*pIndex = Index;
return(SNMP_ERRORSTATUS_NOERROR);
}
else
{
//
// if passed in value is greater, continue on to
// the next item. The list is in ascending order
//
if (Add > pAddKey->IpAdd)
{
continue;
}
else
{
//
// the list element is > passed in value,
// break out of the loop
//
break;
}
}
}
//
// if no match, but field is GetNext, return the (highest index - 1)
// reached above. This is because, PnrFindNext will be called by
// the caller
//
if (PduAction == MIB_GETNEXT)
{
if (Index == 0)
{
*pfFirst = TRUE;
}
else
{
*pIndex = Index - 1;
}
ErrStat = SNMP_ERRORSTATUS_NOERROR;
goto Exit;
}
else
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
}
Exit:
return(ErrStat);
}
UINT
PnrFindNext(
INT AddKeyNo,
DWORD NumAddKeys,
PADD_KEY_T pAddKey
)
{
DWORD i;
LONG nextif;
//
// if AddKeyNo is 0 or more, search for the key next to
// the key passed.
//
for (nextif = -1, i = 0 ; i < NumAddKeys; i++)
{
if (AddKeyNo >= 0)
{
if ( (pAddKey + i)->IpAdd <=
(pAddKey + AddKeyNo)->IpAdd)
{
//
// This item is lexicographically less or equal,
// continue
//
continue;
}
else
{
nextif = i;
break;
}
}
else
{
//
// We want the first key
//
nextif = 0;
break;
}
#if 0
//
// if we want the first entry, then continue until
// we get an entry that is lexicographically same or
// greater
//
if (
(nextif < 0)
||
(pAddKey + (i - 1))->IpAdd < (pAddKey + nextif)->IpAdd
)
{
nextif = i;
}
#endif
}
return(nextif);
}
UINT
PnrGetFirst(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
PADD_KEY_T pAddKey = NULL;
DWORD NumAddKeys;
INT Iface;
UINT TableEntryIds[5];
AsnObjectIdentifier TableEntryOid = { OID_SIZEOF(TableEntryIds),
TableEntryIds };
UINT ErrStat;
//
// Get all the address key information
//
EnumAddKeys(KeyType_e, &pAddKey, &NumAddKeys);
//
// If there is no entry in the table, go to the next MIB variable
//
if (NumAddKeys == 0)
{
return(GetNextVar(VarBind, MibPtr));
}
//
// Get the first entry in the table
//
Iface = PnrFindNext(-1, NumAddKeys, pAddKey);
//
// Write the object Id into the binding list and call get
// func
//
SNMP_oidfree( &VarBind->name );
SNMP_oidcpy( &VarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &VarBind->name, &MibPtr->Oid );
//
// The fixed part of the objid is correct. Update the rest.
//
TableEntryIds[0] = 1;
TableEntryIds[1] = (UINT)((pAddKey + Iface)->IpAdd >> 24);
TableEntryIds[2] = (UINT)(((pAddKey + Iface)->IpAdd >> 16)
& 0xFF);
TableEntryIds[3] = (UINT)(((pAddKey + Iface)->IpAdd >> 8)
& 0xFF);
TableEntryIds[4] = (UINT)((pAddKey + Iface)->IpAdd & 0xFF);
SNMP_oidappend( &VarBind->name, &TableEntryOid );
ErrStat = (KeyType_e == PULL_E_KEY)
? PullGet(VarBind, NumAddKeys, pAddKey)
: PushGet(VarBind, NumAddKeys, pAddKey);
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
return(ErrStat);
}
UINT
PullSet(
IN RFC1157VarBind *VarBind
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
ADD_KEY_T AddKey;
#if 0
LPBYTE pTmpB;
#endif
struct in_addr InAddr;
//
// Extract the field that needs to be set
//
Field = VarBind->name.ids[PULLPNR_OIDLEN];
AddKey.IpAdd = (VarBind->name.ids[PNR_OIDLEN + 1] << 24);
AddKey.IpAdd |= (VarBind->name.ids[PNR_OIDLEN + 2] << 16);
AddKey.IpAdd |= (VarBind->name.ids[PNR_OIDLEN + 3] << 8);
AddKey.IpAdd |= VarBind->name.ids[PNR_OIDLEN + 4];
InAddr.s_addr = htonl(AddKey.IpAdd);
//
// The storage must be adequate to contain the new
// string including a NULL terminator.
//
strcpy( (LPSTR)AddKey.asIpAddress, inet_ntoa(InAddr) );
switch(Field)
{
case 1:
if (VarBind->value.asnType != ASN_RFC1155_IPADDRESS)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
#if 0
pTmpB =
VarBind->value.asnValue.string.stream;
NMSMSGF_RETRIEVE_IPADD_M(pTmpB, AddKey.IpAdd);
InAddr.s_addr = htonl(AddKey.IpAdd);
//
// The storage must be adequate to contain the new
// string including a NULL terminator.
//
strcpy(
(LPSTR)AddKey.asIpAddress,
inet_ntoa(InAddr)
);
#endif
#if 0
memcpy( (LPSTR)AddKey.asIpAddress,
VarBind->value.asnValue.string.stream,
VarBind->value.asnValue.string.length );
((LPSTR)AddKey.asIpAddress)
[VarBind->value.asnValue.string.length] = '\0';
#endif
break;
case 2: // SpTime
if (VarBind->value.asnType != ASN_RFC1213_DISPSTRING)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
// The storage must be adequate to contain the new
// string including a NULL terminator.
memcpy( (LPSTR)AddKey.asSpTime,
VarBind->value.asnValue.string.stream,
VarBind->value.asnValue.string.length );
((LPSTR)AddKey.asSpTime)
[VarBind->value.asnValue.string.length] = '\0';
break;
case 3: // TimeInterval
if (VarBind->value.asnType != ASN_INTEGER)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
(AsnInteger)(AddKey.TimeInterval) =
VarBind->value.asnValue.number;
break;
case 4: // MemberPrec
if (VarBind->value.asnType != ASN_INTEGER)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
(AsnInteger)(AddKey.MemberPrec) =
VarBind->value.asnValue.number;
break;
case 5: //fall through
case 6: //fall through
case 7: //fall through
case 8: //fall through
ErrStat = SNMP_ERRORSTATUS_READONLY;
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
if (ErrStat == SNMP_ERRORSTATUS_NOERROR)
{
ErrStat = WriteKeyNValues(PULL_E_KEY, &AddKey, Field);
}
return(ErrStat);
} //PullSet
UINT
WriteKeyNValues(
KEY_TYPE_E KeyType_e,
PADD_KEY_T pAddKey,
DWORD FieldNo
)
{
HKEY AddKeyHdl;
HKEY RootKeyHdl;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
//
// Open the Parameters key and the key under that
//
ErrStat = OpenKey(PARTNERS_E_KEY, NULL, NULL, NULL, TRUE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
ErrStat = OpenKey(KeyType_e, NULL, &RootKeyHdl, NULL, TRUE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
ErrStat = OpenKey(IPADD_E_KEY, pAddKey->asIpAddress, &AddKeyHdl, &RootKeyHdl, TRUE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
switch(FieldNo)
{
case(1):
//
// for this field, we don't need to do anything.
// The field (actually the key) has already been
// created.
//
break;
case(2):
if (KeyType_e == PUSH_E_KEY)
{
MIB_UpdateCountStore =
pAddKey->UpdateCount;
VarInfo[UPD_CNT_E].pRootKey = &AddKeyHdl;
SetVal(&VarInfo[UPD_CNT_E]);
}
else
{
strcpy(MIB_SpTimeStore, pAddKey->asSpTime);
VarInfo[SP_TIME_E].SizeOfData = strlen(pAddKey->asSpTime);
VarInfo[SP_TIME_E].pRootKey = &AddKeyHdl;
SetVal(&VarInfo[SP_TIME_E]);
}
break;
case(3):
MIB_TimeIntervalStore = pAddKey->TimeInterval;
VarInfo[TIME_INTVL_E].pRootKey = &AddKeyHdl;
SetVal(&VarInfo[TIME_INTVL_E]);
break;
case(4):
MIB_MemberPrecStore = pAddKey->MemberPrec;
VarInfo[MEMBER_PREC_E].pRootKey = &AddKeyHdl;
SetVal(&VarInfo[MEMBER_PREC_E]);
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
//
// Let us close the keys that we opened/created
//
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing AddKeyHdl 0x%08lx.\n",
AddKeyHdl
));
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing RootKeyHdl 0x%08lx.\n",
RootKeyHdl
));
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sParametersKey 0x%08lx (fKeyOpen=%s).\n",
sParametersKey, sfParametersKeyOpen ? "TRUE" : "FALSE"
));
RegCloseKey(AddKeyHdl);
CloseReqKey();
/*
RegCloseKey(RootKeyHdl);
RegCloseKey(sParametersKey);
*/
return(SNMP_ERRORSTATUS_NOERROR);
}
UINT
MIB_PullTable(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
//
// if the length indicates a 0 or partial key, then only the get next
// operation is allowed. The field and the full key
// have a length of 5
//
if (VarBind->name.idLength <= (PULLPNR_OIDLEN + 4))
{
if ((Action == MIB_GET) || (Action == MIB_SET))
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
}
return(
MIB_Table(PULL_TABLE_INDEX, Action, MibPtr, VarBind, PULL_E_KEY)
);
}
UINT
MIB_PushTable(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
//
// if the length indicates a 0 or partial key, then only the get next
// operation is allowed. The field and the full key
// have a length of 5.
//
if (VarBind->name.idLength <= (PUSHPNR_OIDLEN + 4))
{
if ((Action == MIB_GET) || (Action == MIB_SET))
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
}
return(
MIB_Table(PUSH_TABLE_INDEX, Action, MibPtr, VarBind, PUSH_E_KEY)
);
}
UINT
MIB_DFTable(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
//
// if the length indicates a 0 or partial key, then only the get next
// operation is allowed. Actually, the length can never
// be < DF_OIDLEN + 1
//
if (VarBind->name.idLength <= (DF_OIDLEN + 1))
{
if ((Action == MIB_GET) || (Action == MIB_SET))
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
Action = MIB_GETFIRST;
}
return(
MIB_Table(DF_TABLE_INDEX, Action, MibPtr, VarBind, PUSH_E_KEY)
);
}
UINT
MIB_DRTable(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
time_t CurrentTime;
DWORD RetStat = WINSINTF_SUCCESS;
if (Action == MIB_SET)
{
return(SNMP_ERRORSTATUS_READONLY);
}
//
// if the length indicates a 0 or partial key, then only the get next
// operation is allowed. Actually, the length can never
// be < DR_OIDLEN + 1
//
if (VarBind->name.idLength <= (DR_OIDLEN + 1))
{
if ((Action == MIB_GET) || (Action == MIB_SET))
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
}
(void)time(&CurrentTime);
if ((CurrentTime - sDRCacheInitTime) > WINSMIB_DR_CACHE_TIME)
{
if ((RetStat = PopulateDRCache()) == WINSINTF_SUCCESS)
{
sDRCacheInitTime = CurrentTime;
}
if ((RetStat != WINSINTF_SUCCESS) || (sRecs.NoOfRecs == 0))
{
if (Action == MIB_GETNEXT)
{
return(GetNextVar(VarBind, MibPtr));
}
else
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
}
}
return(
MIB_Table(DR_TABLE_INDEX, Action, MibPtr, VarBind, PUSH_E_KEY)
);
}
UINT
MIB_Table(
IN DWORD Index,
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind,
IN KEY_TYPE_E KeyType_e
)
{
UINT ErrStat;
switch(Action)
{
case(MIB_GET):
ErrStat = (*Tables[Index].ti_get)(VarBind, 0, NULL);
break;
case(MIB_GETFIRST):
ErrStat = (*Tables[Index].ti_getf)(VarBind, MibPtr, KeyType_e);
break;
case(MIB_GETNEXT):
ErrStat = (*Tables[Index].ti_getn)(VarBind, MibPtr, KeyType_e);
break;
case(MIB_SET):
ErrStat = (*Tables[Index].ti_set)(VarBind);
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
break;
}
return(ErrStat);
} //MIB_Table
UINT
PushSet(
IN RFC1157VarBind *VarBind
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
ADD_KEY_T AddKey;
LPBYTE pTmpB;
struct in_addr InAddr;
Field = VarBind->name.ids[PUSHPNR_OIDLEN];
AddKey.IpAdd = VarBind->name.ids[PNR_OIDLEN + 1] << 24;
AddKey.IpAdd |= (VarBind->name.ids[PNR_OIDLEN + 2] << 16);
AddKey.IpAdd |= (VarBind->name.ids[PNR_OIDLEN + 3] << 8);
AddKey.IpAdd |= VarBind->name.ids[PNR_OIDLEN + 4];
InAddr.s_addr = htonl(AddKey.IpAdd);
//
// The storage must be adequate to contain the new
// string including a NULL terminator.
//
pTmpB = inet_ntoa(InAddr);
if (NULL == pTmpB) {
return SNMP_ERRORSTATUS_GENERR;
}
strcpy( (LPSTR)AddKey.asIpAddress, pTmpB);
switch(Field)
{
case 1:
if (VarBind->value.asnType != ASN_RFC1155_IPADDRESS)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
break;
case 2: // UpdateCount
if (VarBind->value.asnType != ASN_INTEGER)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
(AsnInteger)(AddKey.UpdateCount) =
VarBind->value.asnValue.number;
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
if (ErrStat == SNMP_ERRORSTATUS_NOERROR)
{
ErrStat = WriteKeyNValues(PUSH_E_KEY, &AddKey, Field);
}
return(ErrStat);
} //PushSet
UINT
PushGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumKeys,
IN LPVOID pKey
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
DWORD Index;
DWORD NumAddKeys = NumKeys;
IN PADD_KEY_T pAddKey = pKey;
if (pAddKey == NULL)
{
//
// Call EnumAddresses only if we have not been invoked by PnrGetNext
//
EnumAddKeys(PUSH_E_KEY, &pAddKey, &NumAddKeys);
}
ErrStat = PnrMatch(VarBind, NumAddKeys, pAddKey, &Index, &Field,
PUSH_E_KEY, MIB_GET, NULL);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
switch(Field)
{
case 1: //IP address itself
VarBind->value.asnType = ASN_RFC1155_IPADDRESS;
VarBind->value.asnValue.string.length = sizeof(ULONG);
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length
)) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
//
// SNMP expects the MSB to be in the first byte, MSB-1
// to be in the second, ....
//
VarBind->value.asnValue.string.stream[0] =
(BYTE)((pAddKey + Index)->IpAdd >> 24);
VarBind->value.asnValue.string.stream[1] =
(BYTE)(((pAddKey + Index)->IpAdd >> 16) & 0xFF);
VarBind->value.asnValue.string.stream[2] =
(BYTE)(((pAddKey + Index)->IpAdd >> 8) & 0xFF);
VarBind->value.asnValue.string.stream[3] =
(BYTE)((pAddKey + Index)->IpAdd & 0xFF );
VarBind->value.asnValue.address.dynamic = TRUE;
break;
case 2: // UpdateCount
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)((pAddKey + Index)->
UpdateCount);
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
Exit:
if ((pKey == NULL) && (pAddKey != NULL))
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pAddKey);
}
return(ErrStat);
} // PushGet
UINT
EnumAddKeys(
KEY_TYPE_E KeyType_e,
PADD_KEY_T *ppAddKey,
LPDWORD pNumAddKeys
)
{
LONG RetVal;
TCHAR KeyName[20]; // will hold name of subkey of
// PULL/PUSH records. These keys are IP
// addresses for which 20 is a
// big enough size
#ifdef UNICODE
CHAR AscKeyName[20];
#endif
DWORD KeyNameSz;
FILETIME LastWrite;
DWORD BuffSize;
HKEY SubKey;
DWORD ValTyp;
DWORD Sz;
DWORD NoOfPnrs = 0; //# of PULL or PUSH pnrs
DWORD NoOfVals;
HKEY KeyHdl;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
PADD_KEY_T pAddKey;
PADD_KEY_T pAddKeySave;
DWORD IndexOfPnr;
HANDLE PrHeapHdl;
*pNumAddKeys = 0; //init to 0
PrHeapHdl = GetProcessHeap();
/*
* Open the key (PARTNERS)
*/
ErrStat = OpenKey(PARTNERS_E_KEY, NULL, NULL, NULL, FALSE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
//
// Open the Pull/Push key
//
ErrStat = OpenKey(KeyType_e, NULL, &KeyHdl, NULL, FALSE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
CloseReqKey();
return(ErrStat);
}
else //key was successfully opened
{
/*
* Query the key. The subkeys are IP addresses of PULL
* partners.
*/
GetKeyInfo(
KeyHdl,
&NoOfPnrs,
&NoOfVals //ignored
);
if (NoOfPnrs == 0)
{
*ppAddKey = NULL;
}
else
{
//
// Allocate buffer big enough to hold data for
// the number of subkeys found under the PULL key
//
BuffSize = sizeof(ADD_KEY_T) * NoOfPnrs;
*ppAddKey = HeapAlloc(
PrHeapHdl,
HEAP_NO_SERIALIZE |
HEAP_GENERATE_EXCEPTIONS |
HEAP_ZERO_MEMORY,
BuffSize
);
if (NULL == *ppAddKey) {
return SNMP_ERRORSTATUS_RESOURCEUNAVAILABLE;
}
pAddKey = *ppAddKey;
pAddKeySave = pAddKey;
/*
* For each key, get the values
*/
for(
IndexOfPnr = 0;
IndexOfPnr < NoOfPnrs;
IndexOfPnr++
)
{
KeyNameSz = sizeof(KeyName); //init before every call
RetVal = RegEnumKeyEx(
KeyHdl, //handle of Push/Pull key
IndexOfPnr, //key
KeyName,
&KeyNameSz,
NULL, //reserved
NULL, //don't need class name
NULL, //ptr to var. to hold class name
&LastWrite //not looked at by us
);
if (RetVal != ERROR_SUCCESS)
{
break;
}
#ifdef UNICODE
if (wcstombs(AscKeyName, KeyName, KeyNameSz) == -1)
{
DBGPRINT0(ERR,
"Conversion not possible in the current locale\n");
}
AscKeyName[KeyNameSz] = EOS;
NONPORT("Call a comm function to do this")
pAddKey->IpAdd = inet_addr(AscKeyName);
strcpy(pAddKey->asIpAddress, AscKeyName);
#else
pAddKey->IpAdd = inet_addr(KeyName);
strcpy(pAddKey->asIpAddress, KeyName);
#endif
//
// inet_addr returns bytes in network byte order
// (Left to
// Right). Let us convert this into host order. This
// will avoid confusion later on. All formatting
// functions
// expect address to be in host order.
//
pAddKey->IpAdd = ntohl( pAddKey->IpAdd );
RetVal = RegOpenKeyEx(
KeyHdl,
KeyName,
0, //reserved; must be 0
KEY_READ,
&SubKey
);
if (RetVal != ERROR_SUCCESS)
{
CloseReqKey();
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE,
*ppAddKey);
*ppAddKey = NULL;
return(SNMP_ERRORSTATUS_GENERR);
}
if (KeyType_e == PULL_E_KEY)
{
//
// Read in specific time for replication if one
// has been specified
//
GetSpTimeData(SubKey, pAddKey);
Sz = sizeof(pAddKey->TimeInterval);
RetVal = RegQueryValueEx(
SubKey,
WINSCNF_RPL_INTERVAL_NM,
NULL, //reserved; must be NULL
&ValTyp,
(LPBYTE)&(pAddKey->TimeInterval),
&Sz
);
if (RetVal != ERROR_SUCCESS)
{
pAddKey->TimeInterval = 0;
pAddKey->fTimeIntOrUpdCntSet = FALSE;
}
else // a value was read in
{
pAddKey->fTimeIntOrUpdCntSet = TRUE;
}
Sz = sizeof(pAddKey->MemberPrec);
RetVal = RegQueryValueEx(
SubKey,
WINSCNF_MEMBER_PREC_NM,
NULL, //reserved; must be NULL
&ValTyp,
(LPBYTE)&(pAddKey->MemberPrec),
&Sz
);
if (RetVal != ERROR_SUCCESS)
{
pAddKey->MemberPrec = 0;
}
}
else // it is a PUSH record
{
//
// Currently, we don't support periodic
// or specific time replication for Push
// records
//
Sz = sizeof(pAddKey->UpdateCount);
RetVal = RegQueryValueEx(
SubKey,
WINSCNF_UPDATE_COUNT_NM,
NULL,
&ValTyp,
(LPBYTE)&(pAddKey->UpdateCount),
&Sz
);
if (RetVal != ERROR_SUCCESS)
{
pAddKey->UpdateCount = 0;
pAddKey->fTimeIntOrUpdCntSet = FALSE;
}
else
{
pAddKey->fTimeIntOrUpdCntSet = TRUE;
}
}
pAddKey->NoOfRpls = 0;
pAddKey->NoOfCommFails = 0;
WINS_ASSIGN_INT_TO_VERS_NO_M(pAddKey->VersNo, 0);
RegCloseKey(SubKey);
pAddKey++;
} // end of for {..} for looping over subkeys of PULL
NoOfPnrs = IndexOfPnr;
/*
* Close the key
*/
// RegCloseKey(KeyHdl);
} //end of else (key could not be opened)
if ((NoOfPnrs > 0) && (KeyType_e == PULL_E_KEY))
{
DWORD Status;
DWORD i, j;
WINSINTF_RESULTS_NEW_T ResultsN;
WINSINTF_RESULTS_T Results;
handle_t BindHdl;
PWINSINTF_RPL_COUNTERS_T pTmp;
PWINSINTF_ADD_VERS_MAP_T pTmp2;
BOOL fOld = FALSE;
// pAddKey = *ppAddKey;
BindHdl = WinsBind(&sBindData);
ResultsN.WinsStat.NoOfPnrs = 0;
ResultsN.WinsStat.pRplPnrs = NULL;
ResultsN.pAddVersMaps = NULL;
if ((Status = WinsStatusNew(BindHdl, WINSINTF_E_STAT, &ResultsN)) ==
RPC_S_PROCNUM_OUT_OF_RANGE)
{
Results.WinsStat.NoOfPnrs = 0;
Results.WinsStat.pRplPnrs = NULL;
Status = WinsStatus(BindHdl, WINSINTF_E_STAT, &Results);
fOld = TRUE;
}
PERF("Can be speeded up by restructuring the data structure and code on the")
PERF("Wins side")
if (Status == WINSINTF_SUCCESS)
{
DWORD NoOfRplPnrs;
DWORD NoOfOwners;
//
// Get the stats for comm. with pnrs. For this we
// compare each member that we found in the registry
// with all members returned in the WinsStat structure
// until there is a match. If there is no match, we
// make the values of the stats 0.
//
NoOfRplPnrs = fOld ? Results.WinsStat.NoOfPnrs :
ResultsN.WinsStat.NoOfPnrs;
if (NoOfRplPnrs > 0)
{
pTmp = fOld ? Results.WinsStat.pRplPnrs :
ResultsN.WinsStat.pRplPnrs;
for (j=0; j < NoOfRplPnrs; j++, pTmp++)
{
pAddKey = pAddKeySave; //init to the first element
for (i = 0; i < NoOfPnrs; i++, pAddKey++)
{
if (pAddKey->IpAdd == pTmp->Add.IPAdd)
{
pAddKey->NoOfRpls = pTmp->NoOfRpls;
pAddKey->NoOfCommFails =
pTmp->NoOfCommFails;
break;
}
}
}
// WinsFreeMem(fOld ? Results.WinsStat.pRplPnrs : ResultsN.WinsStat.pRplPnrs); // deallocation at the end of the if branch - bug #187206
}
//
// Add the highest vers. no. for each pnr
//
pTmp2 = fOld ? &Results.AddVersMaps[1] :
(ResultsN.pAddVersMaps + 1);
NoOfOwners = fOld ? Results.NoOfOwners : ResultsN.NoOfOwners;
NOTE("This is an assumption that we should not rely on in the future")
//
// We start from 1 since 0 is always the local WINS.
//
for (i = 1; i < NoOfOwners; i++, pTmp2++)
{
pAddKey = pAddKeySave;
for (j = 0; j < NoOfPnrs; j++, pAddKey++)
{
if (pAddKey->IpAdd == pTmp2->Add.IPAdd)
{
pAddKey->VersNo = pTmp2->VersNo;
break;
}
}
}
if (!fOld)
{
WinsFreeMem( ResultsN.pAddVersMaps);
}
WinsFreeMem( fOld? Results.WinsStat.pRplPnrs : ResultsN.WinsStat.pRplPnrs );
}
WinsUnbind(&sBindData, BindHdl);
}
if (NoOfPnrs > 1)
{
qsort((LPVOID)*ppAddKey,(size_t)NoOfPnrs,sizeof(ADD_KEY_T),CompareAdd );
}
}
CloseReqKey();
*pNumAddKeys = NoOfPnrs;
if ((*pNumAddKeys == 0) && (*ppAddKey != NULL))
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, *ppAddKey);
*ppAddKey = NULL;
}
return (ErrStat);
} // EnumAddKeys
UINT
GetKeyInfo(
IN HKEY Key,
OUT LPDWORD pNoOfSubKeys,
OUT LPDWORD pNoOfVals
)
/*++
Routine Description:
This function is called to get the number of subkeys under a key
Arguments:
Key - Key whose subkey count has to be determined
KeyType_e
pNoOfSubKeys
Externals Used:
None
Return Value:
None
Error Handling:
Called by:
GetPnrInfo()
Side Effects:
Comments:
None
--*/
{
TCHAR ClsStr[40];
DWORD ClsStrSz = sizeof(ClsStr);
DWORD LongestKeyLen;
DWORD LongestKeyClassLen;
DWORD LongestValueNameLen;
DWORD LongestValueDataLen;
DWORD SecDesc;
LONG RetVal;
FILETIME LastWrite;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
/*
Query the key.
*/
RetVal = RegQueryInfoKey(
Key,
ClsStr,
&ClsStrSz,
NULL, //must be NULL, reserved
pNoOfSubKeys,
&LongestKeyLen,
&LongestKeyClassLen,
pNoOfVals,
&LongestValueNameLen,
&LongestValueDataLen,
&SecDesc,
&LastWrite
);
if (RetVal != ERROR_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
return (ErrStat);
}
VOID
GetSpTimeData(
HKEY SubKey,
PADD_KEY_T pAddKey
)
/*++
Routine Description:
This function is called to get the specific time and period information
for a PULL/PUSH record.
Arguments:
SubKey - Key of a WINS under the Pull/Push key
Externals Used:
None
Return Value:
Success status codes -- WINS_SUCCESS
Error status codes -- WINS_NO_SP_TIME
Error Handling:
Called by:
GetPnrInfo
Side Effects:
Comments:
None
--*/
{
DWORD ValTyp;
DWORD Sz;
LONG RetVal;
pAddKey->fSpTimeSet = FALSE;
FUTURES("Do internationalization of strings here")
Sz = sizeof(pAddKey->asSpTime);
RetVal = RegQueryValueEx(
SubKey,
WINSCNF_SP_TIME_NM,
NULL, //reserved; must be NULL
&ValTyp,
pAddKey->asSpTime,
&Sz
);
//PERF(If memory is initialized to 0, we don't need to do the following
//
// If the user has not specifed a specific time, then we use
// the current time as the specific time. For current time,
// the interval is 0
//
if (RetVal == ERROR_SUCCESS)
{
pAddKey->fSpTimeSet = TRUE;
}
else
{
pAddKey->asSpTime[0] = EOS;
}
return;
}
int
__cdecl
CompareAdd(
const VOID *pKey1,
const VOID *pKey2
)
{
const PADD_KEY_T pAddKey1 = (PADD_KEY_T)pKey1;
const PADD_KEY_T pAddKey2 = (PADD_KEY_T)pKey2;
return(pAddKey1->IpAdd - pAddKey2->IpAdd);
}
UINT
GetNextVar(
IN RFC1157VarBind *pVarBind,
IN MIB_ENTRY *pMibPtr
)
{
UINT ErrStat;
while (pMibPtr != NULL)
{
if (pMibPtr->MibNext != NULL)
{
//
// Setup var bind name of NEXT MIB variable
//
SNMP_oidfree( &pVarBind->name );
SNMP_oidcpy( &pVarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &pVarBind->name, &pMibPtr->MibNext->Oid );
//
// If the func. ptr is NULL and the type of the mib variable
// is anything but OPAQUE, call function to process the
// MIB variable
//
if (
(pMibPtr->MibNext->MibFunc != NULL)
&&
(pMibPtr->MibNext->Type != ASN_RFC1155_OPAQUE)
)
{
ErrStat = (*pMibPtr->MibNext->MibFunc)( MIB_GETFIRST,
pMibPtr->MibNext, pVarBind );
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
goto Exit;
}
break;
}
else
{
pMibPtr = pMibPtr->MibNext;
}
}
else
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
break;
}
}
if (pMibPtr == NULL)
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
}
Exit:
return(ErrStat);
}
UINT
EnumDFValues(
PDATAFILE_INFO_T *ppDFValues,
LPDWORD pNumDFValues
)
/*++
Routine Description:
This function gets the names of all the datafiles that need to
be used for initializing WINS.
Arguments:
Externals Used:
None
Return Value:
Success status codes -- WINS_SUCCESS
Error status codes -- WINS_FAILURE
Error Handling:
Called by:
Side Effects:
Comments:
None
--*/
{
LONG RetVal;
DWORD BuffSize;
STATUS RetStat = WINS_SUCCESS;
DWORD NoOfSubKeys;
DWORD NoOfDFValues;
UINT ErrStat;
DWORD n;
*pNumDFValues = 0;
*ppDFValues = NULL;
n = 0;
ErrStat = OpenKey(PARAMETERS_E_KEY, NULL, NULL, NULL, FALSE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
ErrStat = OpenKey(DATAFILES_E_KEY, NULL, &sDatafilesKey, NULL, FALSE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
CloseReqKey();
return(ErrStat);
}
try {
//
// Get the count of data files listed under the DATAFILES
// key
//
GetKeyInfo(
sDatafilesKey,
&NoOfSubKeys, //ignored
&NoOfDFValues
);
if (NoOfDFValues > 0)
{
DWORD Index;
PDATAFILE_INFO_T pTmp;
#if 0
TCHAR ValNmBuff[MAX_PATH];
#endif
DWORD ValNmBuffSz;
//
// Allocate buffer big enough to hold data for
// the number of values found under the Datafiles key
//
BuffSize = DATAFILE_INFO_SZ * NoOfDFValues;
pTmp = HeapAlloc(
GetProcessHeap(),
HEAP_NO_SERIALIZE |
HEAP_GENERATE_EXCEPTIONS |
HEAP_ZERO_MEMORY,
BuffSize
);
if (pTmp != NULL)
{
*ppDFValues = pTmp;
}
else
{
Index = 0;
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
/*
* Get the values
*/
for(
Index = 0, n = 0;
Index < NoOfDFValues;
Index++
)
{
ValNmBuffSz = sizeof(pTmp->ValNm); //init before
// every call
BuffSize = WINSMIB_FILE_INFO_SIZE;
RetVal = RegEnumValue(
sDatafilesKey,
Index, //value index
pTmp->ValNm,
&ValNmBuffSz,
(LPDWORD)NULL, //reserved
&pTmp->StrType,
(LPBYTE)(pTmp->FileNm),//ptr to var. to
//hold name of
//datafile
&BuffSize //not looked at by us
);
if (RetVal != ERROR_SUCCESS)
{
continue;
}
pTmp->FileNm[BuffSize] = EOS;
//
// if StrType is not REG_SZ or REG_EXPAND_SZ, go to
// the next Value
//
if (
(pTmp->StrType != REG_EXPAND_SZ)
&&
(pTmp->StrType != REG_SZ)
)
{
continue;
}
n++;
pTmp = (PDATAFILE_INFO_T)((LPTCH)pTmp +
DATAFILE_INFO_SZ);
}
Exit:
if (n > 1)
{
qsort(
(LPVOID)*ppDFValues,
(size_t)n,
sizeof(DATAFILE_INFO_T),
CompareIndexes
);
}
*pNumDFValues = n;
}
} // end of try ..
except (EXCEPTION_EXECUTE_HANDLER) {
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: WinsCnfGetNamesOfDataFiles. Exception = (%d).\n",
GetExceptionCode()
));
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
CloseReqKey();
if ((*pNumDFValues == 0) && (*ppDFValues != NULL))
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, *ppDFValues);
}
return(ErrStat);
}
UINT
DFGet(
IN RFC1157VarBind *VarBind,
IN DWORD NumValues,
IN LPVOID pValues
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Index;
DWORD i;
DWORD NumDFValues = NumValues;
PDATAFILE_INFO_T pDFValues;
PVOID pDFValuesSv;
INT iValNm;
//
// Get the index of the file to get. If the Index is more than
// the # of files, we return an error.
//
Index = VarBind->name.ids[VarBind->name.idLength - 1];
if (Index == 0)
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
EnumDFValues(&pDFValues, &NumDFValues);
pDFValuesSv = pDFValues;
for (i=0; i < NumDFValues; i++, pDFValues++)
{
//
// atoi returns a 0 if it can not do a conversion, so if
// somebody other than an snmp agent messes with the
// registry names and introduces alphabets, atoi will return
// 0 and we will not see a match
//
iValNm = atoi(pDFValues->ValNm);
if (iValNm == (INT)Index)
{
break;
}
}
if (i == NumDFValues)
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
goto Exit;
}
//
// Initialize VarBind fields with the type, length, and value
//
VarBind->value.asnType = ASN_RFC1213_DISPSTRING;
VarBind->value.asnValue.string.length =
strlen((LPSTR)(pDFValues->FileNm));
if ( NULL == (VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(CHAR))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)(pDFValues->FileNm),
VarBind->value.asnValue.string.length );
VarBind->value.asnValue.string.dynamic = TRUE;
Exit:
//
// If we allocated memory for storing datafiles info, deallocate it
// now
//
if (pDFValuesSv != NULL)
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pDFValuesSv);
}
return(ErrStat);
}
UINT
DFGetNext(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
DWORD NumDFValues;
INT Index;
PDATAFILE_INFO_T pDFValues;
PVOID pDFValuesSv;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD i;
INT iValNm;
BOOL fMatch = FALSE;
UNREFERENCED_PARAMETER(KeyType_e);
//
// Read in all ip address keys. For each key, the values of its fields
// is stored in the PDATAFILE_INFO structure. The number of
// files found is stored in NumDFValues
//
EnumDFValues(&pDFValues, &NumDFValues);
pDFValuesSv = pDFValues;
//
// Check if the name passed matches any in the table (i.e. table of
// of ADD_KEY_T structures. If there is a match, the address
// of the ip address key and the matching field's no. are returned
//
Index = VarBind->name.ids[DF_OIDLEN + 1];
// Index = VarBind->name.ids[VarBind->name.idLength - 1];
for (i=0; i < NumDFValues; i++, pDFValues++)
{
iValNm = atoi(pDFValues->ValNm);
if (iValNm == Index)
{
fMatch = TRUE;
break;
}
if (iValNm > Index)
{
break;
}
}
//
// if the index specified is higher than all existing indices or if
// match was with the last entry in the list, get to next var.
//
if ((i == 0) || (i >= (NumDFValues - 1)))
{
if (pDFValuesSv != NULL)
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pDFValuesSv);
}
return(GetNextVar(VarBind, MibPtr));
}
//
// Since the operation is GET_NEXT, get the next Value number
// If there is no next file, we call the MibFunc of the next MIB entry.
// Put the index of the next datafile
//
if (fMatch)
{
++pDFValues;
}
VarBind->name.ids[VarBind->name.idLength - 1] = atoi(pDFValues->ValNm);
//
// Get the value
//
//
// Initialize VarBind fields with the type, length, and value
//
VarBind->value.asnType = ASN_RFC1213_DISPSTRING;
VarBind->value.asnValue.string.length =
strlen((LPSTR)(pDFValues->FileNm));
if ( NULL == (VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(CHAR))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)(pDFValues->FileNm),
VarBind->value.asnValue.string.length );
Exit:
if (pDFValuesSv != NULL)
{
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pDFValuesSv);
}
return(ErrStat);
}
UINT
DFGetFirst(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
PDATAFILE_INFO_T pDFValues;
DWORD NumDFValues;
UINT TableEntryId[2];
AsnObjectIdentifier TableEntryOid = { OID_SIZEOF(TableEntryId),
TableEntryId };
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
UNREFERENCED_PARAMETER(KeyType_e);
//
// Get all the address key information
//
PERF("Get the first entry only. Since we won't have very many entries, this")
PERF("is ok. When a cache is implemented, this will serve to populate the")
PERF("cache")
EnumDFValues(&pDFValues, &NumDFValues);
//
// If there is no entry in the table, go to the next MIB variable
//
if (NumDFValues == 0)
{
return(GetNextVar(VarBind, MibPtr));
}
//
// Write the object Id into the binding list and call get
// func
//
SNMP_oidfree( &VarBind->name );
SNMP_oidcpy( &VarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &VarBind->name, &MibPtr->Oid );
//
// The fixed part of the objid is correct. Update the rest.
//
TableEntryId[0] = 2; //put 2 to access the datafile name
#if 0
TableEntryId[1] = 1; //put 1 (for the datafile index). This is
//used for indexing the row of the table
#endif
TableEntryId[1] = atoi(pDFValues->ValNm);
SNMP_oidappend( &VarBind->name, &TableEntryOid );
//
// Initialize VarBind fields with the type, length, and value
//
VarBind->value.asnType = ASN_RFC1213_DISPSTRING;
VarBind->value.asnValue.string.length =
strlen((LPSTR)(pDFValues->FileNm));
if ( NULL == (VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(CHAR))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
(void)memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)(pDFValues->FileNm),
VarBind->value.asnValue.string.length );
#if 0
//
// get the file name
//
ErrStat = DFGet(VarBind, NumDFValues, pDFValues);
#endif
Exit:
HeapFree(GetProcessHeap(), HEAP_NO_SERIALIZE, pDFValues);
return(ErrStat);
}
UINT
DFSet(
IN RFC1157VarBind *pVarBind
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Index;
DATAFILE_INFO_T DFValue;
#if 0
PDATAFILE_INFO_T pDFValues;
#endif
Index = pVarBind->name.ids[pVarBind->name.idLength - 1];
if (Index == 0)
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
if ( pVarBind->value.asnType != ASN_RFC1213_DISPSTRING)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
#if 0
// The storage must be adequate to contain the new
// string including a NULL terminator.
memcpy( (LPSTR)DFValue.FileNm,
pVarBind->value.asnValue.string.stream,
pVarBind->value.asnValue.string.length );
((LPSTR)DFValue.FileNm)[pVarBind->value.asnValue.string.length] = '\0';
#endif
ErrStat = WriteDFValue(pVarBind, &DFValue, Index);
return(ErrStat);
} //DFSet
UINT
WriteDFValue(
IN RFC1157VarBind *pVarBind,
PDATAFILE_INFO_T pDFValue,
DWORD Index
)
{
//
// remove pDFValue as an argument. Use local
//
TCHAR ValNmBuff[MAX_PATH];
DWORD ValNmBuffSz = MAX_PATH;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
LONG RetVal;
if (pVarBind->value.asnType != ASN_RFC1213_DISPSTRING)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
if (
pVarBind->value.asnValue.string.stream[0] == '%')
{
pDFValue->StrType = REG_EXPAND_SZ;
}
else
{
pDFValue->StrType = REG_SZ;
}
//
// Open the Parameters key and the Datafiles key under that
//
ErrStat = OpenKey(PARAMETERS_E_KEY, NULL, NULL, NULL, TRUE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
ErrStat = OpenKey(DATAFILES_E_KEY, NULL, NULL, NULL, TRUE);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
//
// If the index is within the range that we have in the registry,
// let us get the name of the value that stores the datafile name
//
// We get the name because we don't know what it is. If we have
// to overwrite the name, we need to know what it is first.
//
sprintf(ValNmBuff, "%d", Index);
//
// Set the name
//
RetVal = RegSetValueEx(
sDatafilesKey,
ValNmBuff,
0, //reserved -- must be 0
pDFValue->StrType,
pVarBind->value.asnValue.string.stream,
pVarBind->value.asnValue.string.length
);
if (RetVal != ERROR_SUCCESS)
{
SNMPDBG((
SNMP_LOG_ERROR,
"WINSMIB: Could not set value of %s.\n",
pVarBind->value.asnValue.string.stream
));
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
//
// Let us close the keys that we opened/created
//
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sParametersKey 0x%08lx (fKeyOpen=%s).\n",
sParametersKey, sfParametersKeyOpen ? "TRUE" : "FALSE"
));
SNMPDBG((
SNMP_LOG_VERBOSE,
"WINSMIB: Closing sDatafilesKey 0x%08lx (fKeyOpen=%s).\n",
sDatafilesKey, sfDatafilesKeyOpen ? "TRUE" : "FALSE"
));
CloseReqKey();
/*
RegCloseKey(sParametersKey);
RegCloseKey(sDatafilesKey);
*/
return(ErrStat);
}
//
// HandleCmd
// Performs specific actions on the different Cmd MIB variable
//
// Notes:
//
// Return Codes:
// Standard PDU error codes.
//
// Error Codes:
// None.
//
UINT HandleCmd(
IN UINT Action,
IN MIB_ENTRY *MibPtr,
IN RFC1157VarBind *VarBind
)
{
WINSINTF_RESULTS_T Results;
handle_t BindHdl;
DWORD Status;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
switch ( Action )
{
case MIB_SET:
if ((ErrStat = MIB_leaf_func( Action, MibPtr, VarBind ))
== SNMP_ERRORSTATUS_NOERROR)
{
ErrStat = ExecuteCmd(MibPtr);
}
break;
case MIB_GETFIRST:
//
// fall through
//
case MIB_GET:
if (
(MibPtr->Storage == &MIB_NoOfWrkThdsStore)
||
(MibPtr->Storage == &MIB_PriorityClassStore)
||
(MibPtr->Storage == &MIB_MaxVersNo_LowWordStore)
||
(MibPtr->Storage == &MIB_MaxVersNo_HighWordStore)
)
{
if (!fWinsMibWinsStatusCnfCalled)
{
Results.WinsStat.NoOfPnrs = 0;
Results.WinsStat.pRplPnrs = NULL;
BindHdl = WinsBind(&sBindData);
Status = WinsStatus(BindHdl, WINSINTF_E_CONFIG, &Results);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
WinsUnbind(&sBindData, BindHdl);
goto Exit;
}
MIB_NoOfWrkThdsStore = Results.NoOfWorkerThds;
if (Results.WinsPriorityClass == NORMAL_PRIORITY_CLASS)
{
MIB_PriorityClassStore = 0;
}
else
{
MIB_PriorityClassStore = 1;
}
MIB_MaxVersNo_LowWordStore = Results.AddVersMaps[0].VersNo.LowPart;
MIB_MaxVersNo_HighWordStore = Results.AddVersMaps[0].VersNo.HighPart;
fWinsMibWinsStatusCnfCalled = TRUE;
WinsUnbind(&sBindData, BindHdl);
}
}
//
// fall through
//
case MIB_GETNEXT:
//
// Call the more generic function to perform the action
//
ErrStat = MIB_leaf_func( Action, MibPtr, VarBind );
break;
default:
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
} // switch
Exit:
return ErrStat;
} // HandleCmd
UINT
ExecuteCmd(
IN MIB_ENTRY *pMibPtr
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
WINSINTF_ADD_T WinsAdd;
LPBYTE pStorage;
handle_t BindHdl;
DWORD Status;
WinsAdd.Len = 4;
WinsAdd.Type = 0;
BindHdl = WinsBind(&sBindData);
//
// For Performance, arrange the following in the order of
// expected frequency.
//
if ( pMibPtr->Storage == &MIB_PullTriggerStore )
{
pStorage = MIB_PullTriggerStore;
WinsAdd.IPAdd = ntohl(*(DWORD*)pStorage);
//NMSMSGF_RETRIEVE_IPADD_M(pStorage, WinsAdd.IPAdd);
Status = WinsTrigger(BindHdl, &WinsAdd, WINSINTF_E_PULL);
if (Status != WINSINTF_SUCCESS)
{
int backupSize = sizeof(MIB_PullTriggerStore) / 2;
// setting back the original value
memcpy( (LPSTR)pMibPtr->Storage, (LPSTR)pMibPtr->Storage + backupSize, backupSize);
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_PushTriggerStore )
{
pStorage = MIB_PushTriggerStore;
WinsAdd.IPAdd = ntohl(*(DWORD*)pStorage);
//NMSMSGF_RETRIEVE_IPADD_M(pStorage, WinsAdd.IPAdd);
Status = WinsTrigger(BindHdl, &WinsAdd, WINSINTF_E_PUSH);
if (Status != WINSINTF_SUCCESS)
{
int backupSize = sizeof(MIB_PushTriggerStore) / 2;
// setting back the original value
memcpy( (LPSTR)pMibPtr->Storage, (LPSTR)pMibPtr->Storage + backupSize, backupSize);
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_DoScavengingStore )
{
if (MIB_DoScavengingStore == 1)
{
Status = WinsDoScavenging(BindHdl);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
}
else
{
if (MIB_DoScavengingStore != 0)
{
MIB_DoScavengingStore = 0;
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
}
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_DoStaticInitStore )
{
LPBYTE pDataFile = MIB_DoStaticInitStore;
WCHAR UcDataFile[WINSMIB_FILE_INFO_SIZE];
if (MIB_DoStaticInitStore[0] == EOS)
{
UcDataFile[0] = (WCHAR)NULL;
}
else
{
MultiByteToWideChar( CP_ACP, 0,
pDataFile, -1, UcDataFile,
WINSMIB_FILE_INFO_SIZE
);
}
Status = WinsDoStaticInit(BindHdl, UcDataFile, FALSE);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_NoOfWrkThdsStore )
{
if (
(MIB_NoOfWrkThdsStore < 1)
||
(MIB_NoOfWrkThdsStore > 4)
)
{
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
goto Exit;
}
Status = WinsWorkerThdUpd(BindHdl, (DWORD)MIB_NoOfWrkThdsStore);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_PriorityClassStore )
{
if (
(MIB_PriorityClassStore < 0)
||
(MIB_PriorityClassStore > 1)
)
{
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
goto Exit;
}
Status = WinsSetPriorityClass(
BindHdl,
(DWORD)MIB_PriorityClassStore);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_ResetCountersStore )
{
Status = WinsResetCounters(BindHdl);
if (Status != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_DeleteDbRecsStore )
{
WINSINTF_VERS_NO_T MaxVersNo, MinVersNo;
WINS_ASSIGN_INT_TO_VERS_NO_M(MaxVersNo, 0);
WINS_ASSIGN_INT_TO_VERS_NO_M(MinVersNo, 0);
pStorage = MIB_DeleteDbRecsStore;
WinsAdd.IPAdd = ntohl(*(DWORD*)pStorage);
//NMSMSGF_RETRIEVE_IPADD_M(pStorage, WinsAdd.IPAdd);
Status = WinsDelDbRecs(BindHdl, &WinsAdd, MinVersNo, MaxVersNo);
if (Status != WINSINTF_SUCCESS)
{
int backupSize = sizeof(MIB_DeleteDbRecsStore) / 2;
// setting back the original value
memcpy( (LPSTR)pMibPtr->Storage, (LPSTR)pMibPtr->Storage + backupSize, backupSize);
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_GetDbRecsStore )
{
if (PopulateDRCache() == WINSINTF_SUCCESS)
{
(VOID)time(&sDRCacheInitTime);
}
else
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
if ( pMibPtr->Storage == &MIB_DeleteWinsStore )
{
pStorage = MIB_DeleteWinsStore;
WinsAdd.IPAdd = ntohl(*(DWORD*)pStorage);
//NMSMSGF_RETRIEVE_IPADD_M(pStorage, WinsAdd.IPAdd);
Status = WinsDeleteWins(BindHdl, &WinsAdd);
if (Status != WINSINTF_SUCCESS)
{
int backupSize = sizeof(MIB_DeleteWinsStore) / 2;
// setting back the original value
memcpy( (LPSTR)pMibPtr->Storage, (LPSTR)pMibPtr->Storage + backupSize, backupSize);
ErrStat = SNMP_ERRORSTATUS_GENERR;
}
goto Exit;
}
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
Exit:
WinsUnbind(&sBindData, BindHdl);
return ErrStat;
}
VOID
WinsMibInit(
VOID
)
{
#if 0
DWORD i;
MIB_ENTRY *pMib;
#endif
//
// We use named pipe to communicate with WINS when it is on
// the same machine since it is faster than TCP/IP. We don't
// use LRPC since WINS does not listen on that (to minimize
// on thread usage)
//
sBindData.fTcpIp = TRUE;
sBindData.pServerAdd = LOCAL_ADD;
sBindData.pPipeName = NULL;
// InitializeCriticalSection(&WinsMibCrtSec);
#if 0
pMib = Mib;
for (i=1; i < (MIB_num_variables + 1); i++, pMib++)
{
if (pMib->
pMib->MibNext = &Mib[i];
}
for (i=0; i < NUM_TABLES; i++)
{
}
#endif
return;
}
UINT
DRGet(
IN RFC1157VarBind *VarBind,
IN DWORD FieldParam,
IN LPVOID pRowParam
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
PWINSINTF_RECORD_ACTION_T pRow = NULL;
DWORD i, n;
LPBYTE pTmp;
//
// if the row was passed (for instance from DRGetNext), skip
// the search part
//
if (pRowParam == NULL)
{
ErrStat = DRMatch(VarBind, &pRow, &i /*not used*/ , &Field,
MIB_GET, NULL);
if (
(ErrStat != SNMP_ERRORSTATUS_NOERROR)
||
(pRow == NULL)
||
(pRow->State_e == WINSINTF_E_DELETED)
)
{
// bug #235928 - if the first condition in the above if is true, then the
// derefferencing pRow causes a first chance exception!
// if (pRow->State_e == WINSINTF_E_DELETED)
if (ErrStat == SNMP_ERRORSTATUS_NOERROR)
{
ErrStat = SNMP_ERRORSTATUS_NOSUCHNAME;
}
return(ErrStat);
}
}
else
{
pRow = pRowParam;
Field = FieldParam;
}
switch(Field)
{
case 1: //name
VarBind->value.asnType = ASN_OCTETSTRING;
VarBind->value.asnValue.string.length = pRow->NameLen;
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length
)) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
memcpy( VarBind->value.asnValue.string.stream,
(LPSTR)(pRow->pName),
VarBind->value.asnValue.string.length );
VarBind->value.asnValue.string.dynamic = TRUE;
break;
case 2: // address(es)
VarBind->value.asnType = ASN_OCTETSTRING;
if (
(pRow->TypOfRec_e == WINSINTF_E_UNIQUE)
||
(pRow->TypOfRec_e == WINSINTF_E_NORM_GROUP)
)
{
VarBind->value.asnValue.string.length = 4;
}
else
{
VarBind->value.asnValue.string.length =
4 * pRow->NoOfAdds;
}
if ( NULL ==
(VarBind->value.asnValue.string.stream =
SNMP_malloc(VarBind->value.asnValue.string.length *
sizeof(char))) )
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
pTmp = VarBind->value.asnValue.string.stream;
if (
(pRow->TypOfRec_e == WINSINTF_E_UNIQUE)
||
(pRow->TypOfRec_e == WINSINTF_E_NORM_GROUP)
)
{
NMSMSGF_INSERT_IPADD_M(pTmp,pRow->Add.IPAdd);
}
else
{
for (i = 0, n = 0; i < pRow->NoOfAdds/2; i++)
{
NMSMSGF_INSERT_IPADD_M(pTmp,
(pRow->pAdd + n)->IPAdd);
n++;
NMSMSGF_INSERT_IPADD_M(pTmp,
(pRow->pAdd + n)->IPAdd);
n++;
}
}
VarBind->value.asnValue.string.dynamic = TRUE;
break;
case 3: // Record Type
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)(pRow->TypOfRec_e);
break;
case 4: //Persistence Type
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)pRow->fStatic;
break;
case 5: //State
VarBind->value.asnType = ASN_INTEGER;
VarBind->value.asnValue.number =
(AsnInteger)pRow->State_e;
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
Exit:
return(ErrStat);
}
UINT
DRGetNext(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
DWORD OidIndex;
DWORD FieldNo;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Index;
DWORD i;
LPBYTE pNameChar;
UINT TableEntryIds[NMSDB_MAX_NAM_LEN];
BOOL fFirst;
AsnObjectIdentifier TableEntryOid = { OID_SIZEOF(TableEntryIds),
TableEntryIds };
PWINSINTF_RECORD_ACTION_T pRow;
//
// If there is no entry in the table, go to the next MIB variable
//
if (sRecs.NoOfRecs == 0)
{
return(GetNextVar(VarBind, MibPtr));
}
//
// Check if the name passed matches any in the table (i.e. table of
// of WINSINTF_RECORD_ACTION_T structures. If there is a match, the
// address of the structure and the matching field's no. are returned
//
ErrStat = DRMatch(VarBind, &pRow, &Index, &FieldNo, MIB_GETNEXT, &fFirst);
if (ErrStat != SNMP_ERRORSTATUS_NOERROR)
{
return(ErrStat);
}
//
// Since the operation is GETNEXT, get the next name (i.e. one
// that is lexicographically bigger. If there is none, we must increment
// the field value and move back to the lexically first item in the table
// If the new field value is more than the largest supported, we call
// the MibFunc of the next MIB entry.
//
// sRecs.NoOfRecs > 0 since otherwise we won't be here.
//
//
// If we are at the last record and this is not that case where no name
// was passed to us, then increment the field and if it is still within
// bounds, get the first record in the cache
//
//
if ((Index == (sRecs.NoOfRecs - 1)) && !fFirst)
{
if (++FieldNo > NO_FLDS_IN_DR)
{
return(GetNextVar(VarBind, MibPtr));
}
else
{
Index = 0;
pRow = (PWINSINTF_RECORD_ACTION_T)sRecs.pRow;
}
}
else
{
//
// no name was passed, so we need to get the field of the first
// record in the table
//
if (fFirst)
{
pRow = (PWINSINTF_RECORD_ACTION_T)sRecs.pRow;
}
else
{
//
// Get the field of the next record in the cache
//
Index++;
pRow++;
}
while(pRow->State_e == WINSINTF_E_DELETED)
{
if (Index == (sRecs.NoOfRecs - 1))
{
if (++FieldNo > NO_FLDS_IN_DR)
{
return(GetNextVar(VarBind, MibPtr));
}
else
{
Index = 0;
pRow = (PWINSINTF_RECORD_ACTION_T)sRecs.pRow;
}
}
else
{
pRow++;
Index++;
}
}
}
//
// Write the object Id into the binding list and call get
// func
//
SNMP_oidfree( &VarBind->name );
SNMP_oidcpy( &VarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &VarBind->name, &MibPtr->Oid );
TableEntryIds[0] = FieldNo;
OidIndex = 1;
pNameChar = pRow->pName;
//
// The fixed part of the objid is correct. Update the rest.
//
for (i = 0; i < pRow->NameLen; i++)
{
TableEntryIds[OidIndex++] = (UINT)*pNameChar++;
}
TableEntryOid.idLength = OidIndex;
SNMP_oidappend( &VarBind->name, &TableEntryOid );
//
// Get the value
//
ErrStat = DRGet(VarBind, FieldNo, pRow);
return(ErrStat);
}
//
// The rpc function WinsRecordAction has changed in that now it takes
// the address of a pointer. On return the buffer allocated by RPC has
// to be freed. Modify this function to account for that. Currently,
// we never call this function so this work is being deferred - 4/28/94.
//
UINT
DRSet(
IN RFC1157VarBind *VarBind
)
{
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
DWORD Field;
LPBYTE pName;
DWORD NameLen;
PWINSINTF_RECORD_ACTION_T pRow;
PWINSINTF_RECORD_ACTION_T pSvRow;
DWORD Index;
DWORD FieldNo;
handle_t BindHdl;
DWORD i;
BOOL fFound = FALSE;
//
// Extract the field that needs to be set
//
Field = VarBind->name.ids[DR_OIDLEN];
switch(Field)
{
//
// Only the state field is settable
//
case 5:
if ( VarBind->value.asnType != ASN_INTEGER)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
if (
(VarBind->value.asnValue.number != WINSINTF_E_RELEASED)
&&
(VarBind->value.asnValue.number != WINSINTF_E_DELETED)
)
{
return(SNMP_ERRORSTATUS_BADVALUE);
}
if (sRecs.NoOfRecs == 0)
return (SNMP_ERRORSTATUS_NOSUCHNAME);
NameLen = VarBind->name.idLength - (DR_OIDLEN + 1);
if ( NULL == (pName = SNMP_malloc(NameLen * sizeof(char))) )
{
return(SNMP_ERRORSTATUS_GENERR);
}
ErrStat = DRMatch(VarBind, &pRow, &Index, &FieldNo, MIB_SET, NULL);
if (ErrStat == SNMP_ERRORSTATUS_NOERROR)
{
fFound = TRUE;
}
else
{
LPBYTE pNameChar = pRow->pName;
DWORD n = DR_OIDLEN + 1;
for (i=0; i<NameLen;i++)
{
*pNameChar = (BYTE)
VarBind->name.ids[n++];
}
pRow->NameLen = NameLen;
}
pRow->fStatic = 1;
if ( VarBind->value.asnValue.number ==
WINSINTF_E_RELEASED)
{
pRow->Cmd_e = WINSINTF_E_RELEASE;
}
else
{
pRow->Cmd_e = WINSINTF_E_DELETE;
}
BindHdl = WinsBind(&sBindData);
pSvRow = pRow;
if ( WinsRecordAction(BindHdl, &pSvRow) != WINSINTF_SUCCESS)
{
ErrStat = SNMP_ERRORSTATUS_GENERR;
goto Exit;
}
WinsFreeMem(pSvRow->pName);
WinsFreeMem(pSvRow->pAdd);
WinsFreeMem(pSvRow);
pRow->State_e = VarBind->value.asnValue.number;
break;
case(1):
case(2):
case(3):
case(4):
ErrStat = SNMP_ERRORSTATUS_READONLY;
break;
default:
ErrStat = SNMP_ERRORSTATUS_BADVALUE;
break;
}
Exit:
WinsUnbind(&sBindData, BindHdl);
return(ErrStat);
} //DRSet
UINT
DRGetFirst(
IN RFC1157VarBind *VarBind,
IN MIB_ENTRY *MibPtr,
IN KEY_TYPE_E KeyType_e
)
{
DWORD OidIndex;
UINT TableEntryIds[NMSDB_MAX_NAM_LEN];
AsnObjectIdentifier TableEntryOid = { OID_SIZEOF(TableEntryIds),
TableEntryIds };
UINT ErrStat;
PTUCHAR pNameChar;
PWINSINTF_RECORD_ACTION_T pRow = (PWINSINTF_RECORD_ACTION_T)sRecs.pRow;
DWORD i;
if (sRecs.NoOfRecs == 0)
{
return(GetNextVar(VarBind, MibPtr));
}
//
// Write the object Id into the binding list and call get
// func
//
SNMP_oidfree( &VarBind->name );
SNMP_oidcpy( &VarBind->name, &MIB_OidPrefix );
SNMP_oidappend( &VarBind->name, &MibPtr->Oid );
//
// The fixed part of the objid is corect. Update the rest.
//
//OidIndex = VarBind->name.idLength;
TableEntryIds[0] = 1;
OidIndex = 1;
pNameChar = pRow->pName;
for (i = 0; i < pRow->NameLen; i++)
{
TableEntryIds[OidIndex++] = (UINT)*pNameChar++;
}
TableEntryOid.idLength = OidIndex;
SNMP_oidappend( &VarBind->name, &TableEntryOid );
ErrStat = DRGet(VarBind, 0, NULL);
return(ErrStat);
}
UINT
DRMatch(
IN RFC1157VarBind *VarBind,
IN PWINSINTF_RECORD_ACTION_T *ppRow,
IN LPDWORD pIndex,
IN LPDWORD pField,
IN UINT PduAction,
OUT LPBOOL pfFirst
)
{
DWORD NameLen;
BYTE Name[NMSDB_MAX_NAM_LEN];
LPBYTE pNameChar = Name;
DWORD NameIndex = DR_OIDLEN + 1;
UINT *pTmp = &VarBind->name.ids[NameIndex];
DWORD i;
PWINSINTF_RECORD_ACTION_T pRow = (PWINSINTF_RECORD_ACTION_T)sRecs.pRow;
UINT ErrStat = SNMP_ERRORSTATUS_NOERROR;
INT CmpVal;
if (pfFirst != NULL)
{
*pfFirst = FALSE;
}
NameLen = VarBind->name.idLength - (DR_OIDLEN + 1);
*pField = VarBind->name.ids[DR_OIDLEN];
//
// if a name has been specified, get it into Name array
//
if (NameLen > 0)
{
for(i=0; i<NameLen; i++)
{
*pNameChar++ = (BYTE)*pTmp++;
}
//
// Compare the name with names in the cache (in ascending order)
//
for (i=0; i < sRecs.NoOfRecs; i++, pRow++)
{
//
// replace with RtlCompareMemory
//
CmpVal = memcmp(Name, pRow->pName, NameLen);
if (CmpVal == 0)
{
*pIndex = i;
*ppRow = pRow;
return(SNMP_ERRORSTATUS_NOERROR);
}
else
{
//
// Passed in name is lexicographically > than
// name being looked at, continue on
//
if (CmpVal > 0)
{
continue;
}
else
{
//
// Passed in name is lexicographically < than
// name being looked at, continue on
//
break;
}
}
}
//
// if the action is not GETNEXT, we return an error, since we
// did not find a matching name
//
if (PduAction != MIB_GETNEXT)
{
return(SNMP_ERRORSTATUS_NOSUCHNAME);
}
else
{
//
// Either the name is lexicographically > than all names
// or we reached a name in the list that is lexicographically
// < it. In the first case, i needs to be decremented by
// 1. *ppRow needs to be initialized to either the last
// row in the table or to the element before the one we
// found to be lexicographically greater.
//
*pIndex = i - 1;
*ppRow = --pRow;
return(SNMP_ERRORSTATUS_NOERROR);
}
}
else // NameLen == 0
{
//
// The action has got to be GETNEXT (see MIB_DRTable)
// which means that pfFirst is not NULL
//
//--ft: prefix bug #444993
*pIndex = 0;
if (pfFirst != NULL)
*pfFirst = TRUE;
}
return(ErrStat);
}
int
__cdecl
CompareNames(
const VOID *pKey1,
const VOID *pKey2
)
{
const PWINSINTF_RECORD_ACTION_T pRow1 = (PWINSINTF_RECORD_ACTION_T)pKey1;
const PWINSINTF_RECORD_ACTION_T pRow2 = (PWINSINTF_RECORD_ACTION_T)pKey2;
ULONG CmpVal;
DWORD LenToCmp = min(pRow1->NameLen, pRow2->NameLen);
PERF("replace with RtlCompareMemory")
CmpVal = memcmp(pRow1->pName, pRow2->pName, LenToCmp);
if (CmpVal == LenToCmp)
{
return(pRow1->NameLen - pRow2->NameLen);
}
else
{
return(CmpVal);
}
}
int
__cdecl
CompareIndexes(
const VOID *pKey1,
const VOID *pKey2
)
{
const PDATAFILE_INFO_T pRow1 = (PDATAFILE_INFO_T)pKey1;
const PDATAFILE_INFO_T pRow2 = (PDATAFILE_INFO_T)pKey2;
PERF("replace with RtlCompareMemory")
return(strcmp(pRow1->ValNm, pRow2->ValNm));
}
DWORD
PopulateDRCache(
VOID
)
{
DWORD RetStat = WINSINTF_SUCCESS;
WINSINTF_VERS_NO_T MaxVersNo, MinVersNo;
handle_t BindHdl;
WINSINTF_ADD_T WinsAdd;
DWORD SvNoOfRecs;
LPVOID pSvRplPnrs;
LPBYTE pStorage;
WINS_ASSIGN_INT_TO_VERS_NO_M(MaxVersNo, 0);
WINS_ASSIGN_INT_TO_VERS_NO_M(MinVersNo, 0);
WinsAdd.Len = 4;
WinsAdd.Type = 0;
pSvRplPnrs = sRecs.pRow;
SvNoOfRecs = sRecs.NoOfRecs;
sRecs.pRow = NULL;
sRecs.NoOfRecs = 0;
pStorage = MIB_GetDbRecsStore;
WinsAdd.IPAdd = ntohl(*(DWORD*)pStorage);
//NMSMSGF_RETRIEVE_IPADD_M(pStorage, WinsAdd.IPAdd);
BindHdl = WinsBind(&sBindData);
RetStat = WinsGetDbRecs(BindHdl, &WinsAdd, MinVersNo, MaxVersNo, &sRecs);
WinsUnbind(&sBindData, BindHdl);
if (RetStat == WINSINTF_SUCCESS)
{
if (sRecs.NoOfRecs > 1)
{
qsort(
(LPVOID)sRecs.pRow,
(size_t)sRecs.NoOfRecs,
sizeof(WINSINTF_RECORD_ACTION_T),
CompareNames
);
}
if (pSvRplPnrs != NULL)
{
WinsFreeMem(pSvRplPnrs);
}
}
else
{
sRecs.NoOfRecs = SvNoOfRecs;
sRecs.pRow = pSvRplPnrs;
}
return(RetStat);
}
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