Leaked source code of windows server 2003
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/*++
Copyright (c) Microsoft Corporation. All rights reserved.
Module Name:
rutil.c
Abstract:
This module contains general utility routines used by umpnpmgr.
PNP_ENTER_SYNCHRONOUS_CALL
PNP_LEAVE_SYNCHRONOUS_CALL
CreateDeviceIDRegKey
IsRootDeviceID
MultiSzAppendW
MultiSzFindNextStringW
MultiSzSearchStringW
MultiSzSizeW
MultiSzDeleteStringW
IsValidDeviceID
IsDevicePhantom
GetDeviceStatus
SetDeviceStatus
ClearDeviceStatus
CopyRegistryTree
PathToString
IsDeviceMoved
MakeKeyVolatile
MakeKeyNonVolatile
OpenLogConfKey
GetActiveService
IsDeviceIdPresent
GetDeviceConfigFlags
MapNtStatusToCmError
IsValidGuid
GuidEqual
GuidFromString
StringFromGuid
Author:
Paula Tomlinson (paulat) 7-12-1995
Environment:
User mode only.
Revision History:
12-July-1995 paulat
Creation and initial implementation.
--*/
//
// includes
//
#include "precomp.h"
#pragma hdrstop
#include "umpnpi.h"
#include "umpnpdat.h"
#pragma warning(push)
#pragma warning(disable:4214) // warning C4214: nonstandard extension used : bit field types other than int
#pragma warning(disable:4201) // warning C4201: nonstandard extension used : nameless struct/union
#include <winsta.h>
#pragma warning(pop)
#include <syslib.h>
//
// global data
//
extern HKEY ghEnumKey; // Key to HKLM\CCC\System\Enum - DO NOT MODIFY
extern HKEY ghServicesKey; // Key to HKLM\CCC\System\Services - DO NOT MODIFY
extern CRITICAL_SECTION PnpSynchronousCall;
//
// Declare data used in GUID->string conversion (from ole32\common\ccompapi.cxx).
//
static const BYTE GuidMap[] = { 3, 2, 1, 0, '-', 5, 4, '-', 7, 6, '-',
8, 9, '-', 10, 11, 12, 13, 14, 15 };
static const WCHAR szDigits[] = TEXT("0123456789ABCDEF");
VOID
PNP_ENTER_SYNCHRONOUS_CALL(
VOID
)
{
EnterCriticalSection(&PnpSynchronousCall);
} // PNP_ENTER_SYNCHRONOUS_CALL
VOID
PNP_LEAVE_SYNCHRONOUS_CALL(
VOID
)
{
LeaveCriticalSection(&PnpSynchronousCall);
} // PNP_LEAVE_SYNCHRONOUS_CALL
BOOL
CreateDeviceIDRegKey(
HKEY hParentKey,
LPCWSTR pDeviceID
)
/*++
Routine Description:
This routine creates the specified device id subkeys in the registry.
Arguments:
hParentKey Key under which the device id key will be created
pDeviceID Device instance ID string to open
Return value:
The return value is TRUE if the function suceeds and FALSE if it fails.
--*/
{
WCHAR szBase[MAX_DEVICE_ID_LEN];
WCHAR szDevice[MAX_DEVICE_ID_LEN];
WCHAR szInstance[MAX_DEVICE_ID_LEN];
HKEY hBaseKey, hDeviceKey, hInstanceKey;
if (!SplitDeviceInstanceString(
pDeviceID, szBase, szDevice, szInstance)) {
return FALSE;
}
//
// just try creating each component of the device id
//
if (RegCreateKeyEx(
hParentKey, szBase, 0, NULL, REG_OPTION_NON_VOLATILE,
KEY_ALL_ACCESS, NULL, &hBaseKey, NULL) != ERROR_SUCCESS) {
return FALSE;
}
if (RegCreateKeyEx(
hBaseKey, szDevice, 0, NULL, REG_OPTION_NON_VOLATILE,
KEY_ALL_ACCESS, NULL, &hDeviceKey, NULL) != ERROR_SUCCESS) {
RegCloseKey(hBaseKey);
return FALSE;
}
if (RegCreateKeyEx(
hDeviceKey, szInstance, 0, NULL, REG_OPTION_NON_VOLATILE,
KEY_ALL_ACCESS, NULL, &hInstanceKey, NULL) != ERROR_SUCCESS) {
RegCloseKey(hBaseKey);
RegCloseKey(hDeviceKey);
return FALSE;
}
RegCloseKey(hBaseKey);
RegCloseKey(hDeviceKey);
RegCloseKey(hInstanceKey);
return TRUE;
} // CreateDeviceIDRegKey
BOOL
IsRootDeviceID(
LPCWSTR pDeviceID
)
/*++
Routine Description:
This routine determines whether the specified device id is the root
device id.
Arguments:
pDeviceID Pointer to a device id string
Return value:
The return value is TRUE if the string is the root device id and
FALSE if it is not.
--*/
{
size_t DeviceIDLen = 0;
ASSERT(ARGUMENT_PRESENT(pDeviceID));
if (FAILED(StringCchLength(
pDeviceID,
MAX_DEVICE_ID_LEN,
&DeviceIDLen))) {
return FALSE;
}
if (CompareString(LOCALE_INVARIANT,
NORM_IGNORECASE,
pDeviceID,
-1,
pszRegRootEnumerator,
-1) == CSTR_EQUAL) {
return TRUE;
}
return FALSE;
} // IsRootDeviceID
BOOL
MultiSzAppendW(
LPWSTR pszMultiSz,
PULONG pulSize,
LPCWSTR pszString
)
/*++
Routine Description:
Appends a string to a multi_sz string.
Arguments:
pszMultiSz Pointer to a multi_sz string
pulSize On input, Size of the multi_sz string buffer in bytes,
On return, amount copied to the buffer (in bytes)
pszString String to append to pszMultiSz
Return value:
The return value is TRUE if the function succeeded and FALSE if an
error occured.
--*/
{
BOOL bStatus = TRUE;
HRESULT hr;
LPWSTR pTail;
ULONG ulSize;
try {
//
// if it's an empty string, just copy it
//
if (*pszMultiSz == L'\0') {
ulSize = (lstrlen(pszString) + 2) * sizeof(WCHAR);
if (ulSize > *pulSize) {
bStatus = FALSE;
goto Clean0;
}
hr = StringCchCopyEx(pszMultiSz,
*pulSize,
pszString,
NULL, NULL,
STRSAFE_NULL_ON_FAILURE |
STRSAFE_IGNORE_NULLS);
ASSERT(SUCCEEDED(hr));
if (FAILED(hr)) {
bStatus = FALSE;
goto Clean0;
}
pszMultiSz[lstrlen(pszMultiSz) + 1] = L'\0'; // add second NULL term char
*pulSize = ulSize;
goto Clean0;
}
//
// first find the end of the multi_sz string
//
pTail = pszMultiSz;
while ((ULONG)(pTail - pszMultiSz) * sizeof(WCHAR) < *pulSize) {
while (*pTail != L'\0') {
pTail++;
}
pTail++; // skip past the null terminator
if (*pTail == L'\0') {
break; // found the double null terminator
}
}
if ((pTail - pszMultiSz + lstrlen(pszString) + 2) * sizeof(WCHAR)
> *pulSize) {
bStatus = FALSE; // the copy would overflow the buffer
goto Clean0;
}
hr = StringCchCopyEx(pTail,
*pulSize,
pszString,
NULL, NULL,
STRSAFE_NULL_ON_FAILURE |
STRSAFE_IGNORE_NULLS);
ASSERT(SUCCEEDED(hr));
if (FAILED(hr)) {
bStatus = FALSE;
goto Clean0;
}
pTail += lstrlen(pszString) + 1;
*pTail = L'\0'; // add second null terminator
//
// return buffer size in bytes
//
*pulSize = (ULONG)((pTail - pszMultiSz + 1)) * sizeof(WCHAR);
Clean0:
NOTHING;
} except(EXCEPTION_EXECUTE_HANDLER) {
bStatus = FALSE;
}
return bStatus;
} // MultiSzAppendW
LPWSTR
MultiSzFindNextStringW(
LPWSTR pMultiSz
)
/*++
Routine Description:
Finds next string in a multi_sz string.
device id.
Arguments:
pMultiSz Pointer to a multi_sz string
Return value:
The return value is a pointer to the next string or NULL.
--*/
{
LPWSTR lpNextString = pMultiSz;
//
// find the next NULL terminator
//
while (*lpNextString != L'\0') {
lpNextString++;
}
lpNextString++; // skip over the NULL terminator
if (*lpNextString == L'\0') {
//
// two NULL terminators in a row means we're at the end
//
lpNextString = NULL;
}
return lpNextString;
} // MultiSzFindNextStringW
BOOL
MultiSzSearchStringW(
IN LPCWSTR pString,
IN LPCWSTR pSubString
)
{
LPCWSTR pCurrent = pString;
//
// compare each string in the multi_sz pString with pSubString
//
while (*pCurrent != L'\0') {
if (lstrcmpi(pCurrent, pSubString) == 0) {
return TRUE;
}
//
// go to the next string
//
while (*pCurrent != L'\0') {
pCurrent++;
}
pCurrent++; // skip past the null terminator
if (*pCurrent == L'\0') {
break; // found the double null terminator
}
}
return FALSE; // pSubString match not found within pString
} // MultiSzSearchStringW
ULONG
MultiSzSizeW(
IN LPCWSTR pString
)
{
LPCWSTR p = NULL;
if (pString == NULL) {
return 0;
}
for (p = pString; *p; p += lstrlen(p)+1) {
//
// this should fall out with p pointing to the
// second null in double-null terminator
//
NOTHING;
}
//
// returns size in WCHAR
//
return (ULONG)(p - pString + 1);
} // MultiSzSizeW
BOOL
MultiSzDeleteStringW(
IN OUT LPWSTR pString,
IN LPCWSTR pSubString
)
{
LPWSTR p = NULL, pNext = NULL, pBuffer = NULL;
ULONG ulSize = 0;
if (pString == NULL || pSubString == NULL) {
return FALSE;
}
for (p = pString; *p; p += lstrlen(p)+1) {
if (lstrcmpi(p, pSubString) == 0) {
//
// found a match, this is the string to remove.
//
pNext = p + lstrlen(p) + 1;
//
// If this is the last string then just truncate it
//
if (*pNext == L'\0') {
*p = L'\0';
*(++p) = L'\0'; // double null-terminator
return TRUE;
}
//
// retrieve the size of the multi_sz string (in bytes)
// starting with the substring after the matching substring
//
ulSize = MultiSzSizeW(pNext) * sizeof(WCHAR);
if (ulSize == 0) {
return FALSE;
}
pBuffer = HeapAlloc(ghPnPHeap, 0, ulSize);
if (pBuffer == NULL) {
return FALSE;
}
//
// Make a copy of the multi_sz string starting at the
// substring immediately after the matching substring
//
memcpy(pBuffer, pNext, ulSize);
//
// Copy that buffer back to the original buffer, but this
// time copy over the top of the matching substring. This
// effectively removes the matching substring and shifts
// any remaining substrings up in multi_sz string.
//
memcpy(p, pBuffer, ulSize);
HeapFree(ghPnPHeap, 0, pBuffer);
return TRUE;
}
}
//
// if we got here, there was no match but I consider this a success
// since the multi_sz does not contain the substring when we're done
// (which is the desired goal)
//
return TRUE;
} // MultiSzDeleteStringW
BOOL
IsValidDeviceID(
IN LPCWSTR pszDeviceID,
IN HKEY hKey,
IN ULONG ulFlags
)
/*++
Routine Description:
This routine checks if the given device id is valid (present, not moved,
not phantom).
Arguments:
pszDeviceID Device instance string to validate
hKey Can specify open registry key to pszDeviceID, also
ulFlag Controls how much verification to do
Return value:
The return value is CR_SUCCESS if the function suceeds and one of the
CR_* values if it fails.
--*/
{
BOOL Status = TRUE;
LONG RegStatus = ERROR_SUCCESS;
WCHAR RegStr[MAX_CM_PATH];
HKEY hDevKey = NULL;
ULONG ulValue = 0, ulSize = sizeof(ULONG);
//
// Does the device id exist in the registry?
//
if (hKey == NULL) {
if (FAILED(StringCchPrintf(
RegStr,
SIZECHARS(RegStr),
L"%s\\%s",
pszRegPathEnum,
pszDeviceID))) {
return FALSE;
}
RegStatus =
RegOpenKeyEx(
HKEY_LOCAL_MACHINE, RegStr, 0,
KEY_READ, &hDevKey);
if (RegStatus != ERROR_SUCCESS) {
return FALSE;
}
} else {
hDevKey = hKey;
}
//-----------------------------------------------------------
// Is the device id present?
//-----------------------------------------------------------
if (ulFlags & PNP_PRESENT) {
if (!IsDeviceIdPresent(pszDeviceID)) {
Status = FALSE;
goto Clean0;
}
}
//-----------------------------------------------------------
// Is it a phantom device id?
//-----------------------------------------------------------
if (ulFlags & PNP_NOT_PHANTOM) {
RegStatus = RegQueryValueEx(
hDevKey, pszRegValuePhantom, NULL, NULL,
(LPBYTE)&ulValue, &ulSize);
if (RegStatus == ERROR_SUCCESS) {
if (ulValue) {
Status = FALSE;
goto Clean0;
}
}
}
//-----------------------------------------------------------
// Has the device id been moved?
//-----------------------------------------------------------
if (ulFlags & PNP_NOT_MOVED) {
if (IsDeviceMoved(pszDeviceID, hDevKey)) {
Status = FALSE;
goto Clean0;
}
}
//-----------------------------------------------------------
// Has the device id been removed?
//-----------------------------------------------------------
if (ulFlags & PNP_NOT_REMOVED) {
ULONG ulProblem = 0, ulStatus = 0;
if (GetDeviceStatus(pszDeviceID, &ulStatus, &ulProblem) == CR_SUCCESS) {
if (ulStatus & DN_WILL_BE_REMOVED) {
Status = FALSE;
goto Clean0;
}
}
}
Clean0:
if ((hKey == NULL) && (hDevKey != NULL)) {
RegCloseKey(hDevKey);
}
return Status;
} // IsValidDeviceID
BOOL
IsDevicePhantom(
IN LPWSTR pszDeviceID
)
/*++
Routine Description:
In this case, the check is actually really "is this not present?". The
only comparison is done against FoundAtEnum. UPDATE: for NT 5.0, the
FoundAtEnum registry value has been obsoleted, it's been replaced by a
simple check for the presense of the devnode in memory.
Arguments:
pszDeviceID Device instance string to validate
Return value:
Returns TRUE if the device is a phantom and FALSE if it isn't.
--*/
{
return !IsDeviceIdPresent(pszDeviceID);
} // IsDevicePhantom
CONFIGRET
GetDeviceStatus(
IN LPCWSTR pszDeviceID,
OUT PULONG pulStatus,
OUT PULONG pulProblem
)
/*++
Routine Description:
This routine retrieves the status and problem values for the given
device instance.
Arguments:
pszDeviceID Specifies the device instance to retrieve info for
pulStatus Returns the device's status
pulProblem Returns the device's problem
Return value:
The return value is CR_SUCCESS if the function suceeds and one of the
CR_* values if it fails.
--*/
{
CONFIGRET Status = CR_SUCCESS;
PLUGPLAY_CONTROL_STATUS_DATA ControlData;
NTSTATUS ntStatus;
memset(&ControlData, 0, sizeof(PLUGPLAY_CONTROL_STATUS_DATA));
RtlInitUnicodeString(&ControlData.DeviceInstance, pszDeviceID);
ControlData.Operation = PNP_GET_STATUS;
ControlData.DeviceStatus = 0;
ControlData.DeviceProblem = 0;
ntStatus = NtPlugPlayControl(PlugPlayControlDeviceStatus,
&ControlData,
sizeof(ControlData));
if (NT_SUCCESS(ntStatus)) {
*pulStatus = ControlData.DeviceStatus;
*pulProblem = ControlData.DeviceProblem;
} else {
Status = MapNtStatusToCmError(ntStatus);
}
return Status;
} // GetDeviceStatus
CONFIGRET
SetDeviceStatus(
IN LPCWSTR pszDeviceID,
IN ULONG ulStatus,
IN ULONG ulProblem
)
/*++
Routine Description:
This routine sets the specified status and problem values for the given
device instance.
Arguments:
pszDeviceID Specifies the device instance to retrieve info for
pulStatus Specifies the device's status
pulProblem Specifies the device's problem
Return value:
The return value is CR_SUCCESS if the function suceeds and one of the
CR_* values if it fails.
--*/
{
CONFIGRET Status = CR_SUCCESS;
PLUGPLAY_CONTROL_STATUS_DATA ControlData;
NTSTATUS ntStatus;
memset(&ControlData, 0, sizeof(PLUGPLAY_CONTROL_STATUS_DATA));
RtlInitUnicodeString(&ControlData.DeviceInstance, pszDeviceID);
ControlData.Operation = PNP_SET_STATUS;
ControlData.DeviceStatus = ulStatus;
ControlData.DeviceProblem = ulProblem;
ntStatus = NtPlugPlayControl(PlugPlayControlDeviceStatus,
&ControlData,
sizeof(ControlData));
if (!NT_SUCCESS(ntStatus)) {
Status = MapNtStatusToCmError(ntStatus);
}
return Status;
} // SetDeviceStatus
CONFIGRET
ClearDeviceStatus(
IN LPCWSTR pszDeviceID,
IN ULONG ulStatus,
IN ULONG ulProblem
)
/*++
Routine Description:
This routine clears the specified status and problem values for the given
device instance.
Arguments:
pszDeviceID Specifies the device instance to retrieve info for
pulStatus Specifies the device's status
pulProblem Specifies the device's problem
Return value:
The return value is CR_SUCCESS if the function suceeds and one of the
CR_* values if it fails.
--*/
{
CONFIGRET Status = CR_SUCCESS;
PLUGPLAY_CONTROL_STATUS_DATA ControlData;
NTSTATUS ntStatus;
memset(&ControlData, 0, sizeof(PLUGPLAY_CONTROL_STATUS_DATA));
RtlInitUnicodeString(&ControlData.DeviceInstance, pszDeviceID);
ControlData.Operation = PNP_CLEAR_STATUS;
ControlData.DeviceStatus = ulStatus;
ControlData.DeviceProblem = ulProblem;
ntStatus = NtPlugPlayControl(PlugPlayControlDeviceStatus,
&ControlData,
sizeof(ControlData));
if (!NT_SUCCESS(ntStatus)) {
Status = MapNtStatusToCmError(ntStatus);
}
return Status;
} // ClearDeviceStatus
CONFIGRET
CopyRegistryTree(
IN HKEY hSrcKey,
IN HKEY hDestKey,
IN ULONG ulOption
)
{
CONFIGRET Status = CR_SUCCESS;
LONG RegStatus = ERROR_SUCCESS;
HKEY hSrcSubKey, hDestSubKey;
WCHAR RegStr[MAX_PATH];
ULONG ulMaxValueName, ulMaxValueData;
ULONG ulDataSize, ulLength, ulType, i;
LPWSTR pszValueName=NULL;
LPBYTE pValueData=NULL;
PSECURITY_DESCRIPTOR pSecDesc;
//----------------------------------------------------------------
// copy all values for this key
//----------------------------------------------------------------
//
// find out the maximum size of any of the value names
// and value data under the source device instance key
//
RegStatus = RegQueryInfoKey(
hSrcKey, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
&ulMaxValueName, &ulMaxValueData, NULL, NULL);
if (RegStatus != ERROR_SUCCESS) {
Status = CR_REGISTRY_ERROR;
goto Clean0;
}
ulMaxValueName++; // size doesn't already include null terminator
//
// allocate a buffer big enough to hold the largest value name and
// the largest value data (note that the max value name is in chars
// (not including the null terminator) and the max value data is
// in bytes
//
pszValueName = HeapAlloc(ghPnPHeap, 0, ulMaxValueName * sizeof(WCHAR));
if (pszValueName == NULL) {
Status = CR_OUT_OF_MEMORY;
goto Clean0;
}
pValueData = HeapAlloc(ghPnPHeap, 0, ulMaxValueData);
if (pValueData == NULL) {
Status = CR_OUT_OF_MEMORY;
goto Clean0;
}
//
// enumerate and copy each value
//
for (i=0; RegStatus == ERROR_SUCCESS; i++) {
ulLength = ulMaxValueName;
ulDataSize = ulMaxValueData;
RegStatus = RegEnumValue(
hSrcKey, i, pszValueName, &ulLength, NULL,
&ulType, pValueData, &ulDataSize);
if (RegStatus == ERROR_SUCCESS) {
RegSetValueEx(
hDestKey, pszValueName, 0, ulType, pValueData,
ulDataSize);
}
}
HeapFree(ghPnPHeap, 0, pszValueName);
pszValueName = NULL;
HeapFree(ghPnPHeap, 0, pValueData);
pValueData = NULL;
//---------------------------------------------------------------
// recursively call CopyRegistryNode to copy all subkeys
//---------------------------------------------------------------
RegStatus = ERROR_SUCCESS;
for (i=0; RegStatus == ERROR_SUCCESS; i++) {
ulLength = MAX_PATH;
RegStatus = RegEnumKey(hSrcKey, i, RegStr, ulLength);
if (RegStatus == ERROR_SUCCESS) {
if (RegOpenKey(hSrcKey, RegStr, &hSrcSubKey) == ERROR_SUCCESS) {
if (RegCreateKeyEx(
hDestKey, RegStr, 0, NULL, ulOption, KEY_ALL_ACCESS,
NULL, &hDestSubKey, NULL) == ERROR_SUCCESS) {
RegGetKeySecurity(hSrcSubKey, DACL_SECURITY_INFORMATION,
NULL, &ulDataSize);
pSecDesc = HeapAlloc(ghPnPHeap, 0, ulDataSize);
if (pSecDesc == NULL) {
Status = CR_OUT_OF_MEMORY;
RegCloseKey(hSrcSubKey);
RegCloseKey(hDestSubKey);
goto Clean0;
}
RegGetKeySecurity(hSrcSubKey, DACL_SECURITY_INFORMATION,
pSecDesc, &ulDataSize);
CopyRegistryTree(hSrcSubKey, hDestSubKey, ulOption);
RegSetKeySecurity(hDestSubKey, DACL_SECURITY_INFORMATION, pSecDesc);
HeapFree(ghPnPHeap, 0, pSecDesc);
RegCloseKey(hDestSubKey);
}
RegCloseKey(hSrcSubKey);
}
}
}
Clean0:
if (pszValueName != NULL) {
HeapFree(ghPnPHeap, 0, pszValueName);
}
if (pValueData != NULL) {
pValueData = NULL;
}
return Status;
} // CopyRegistryTree
BOOL
PathToString(
IN LPWSTR pszString,
IN LPCWSTR pszPath,
IN ULONG ulLen
)
{
LPWSTR p;
HRESULT hr;
hr = StringCchCopyEx(pszString,
ulLen,
pszPath,
NULL, NULL,
STRSAFE_NULL_ON_FAILURE);
ASSERT(SUCCEEDED(hr));
if (FAILED(hr)) {
return FALSE;
}
for (p = pszString; *p; p++) {
if (*p == TEXT('\\')) {
*p = TEXT('&');
}
}
return TRUE;
} // PathToString
BOOL
IsDeviceMoved(
IN LPCWSTR pszDeviceID,
IN HKEY hKey
)
{
HKEY hTempKey;
WCHAR RegStr[MAX_CM_PATH];
PathToString(RegStr, pszDeviceID,MAX_CM_PATH);
if (RegOpenKeyEx(
hKey, RegStr, 0, KEY_READ, &hTempKey) == ERROR_SUCCESS) {
RegCloseKey(hTempKey);
return TRUE;
}
return FALSE;
} // IsDeviceMoved
CONFIGRET
SetKeyVolatileState(
IN LPCWSTR pszParentKey,
IN LPCWSTR pszChildKey,
IN DWORD dwRegOptions
)
{
CONFIGRET Status = CR_SUCCESS;
WCHAR RegStr[MAX_CM_PATH], szTempKey[MAX_CM_PATH];
HKEY hParentKey = NULL, hChildKey = NULL, hKey = NULL;
HKEY hTempKey = NULL;
//---------------------------------------------------------------------
// Convert the registry key specified by pszChildKey (a subkey of
// pszParentKey) to a key with the volatile state specified by copying it to
// a temporary key and recreating the key, then copying the original
// registry info back. This also converts any subkeys of pszChildKey.
//---------------------------------------------------------------------
ASSERT(ARGUMENT_PRESENT(pszParentKey));
ASSERT(ARGUMENT_PRESENT(pszChildKey));
//
// This routine only handles the REG_OPTION bits that specify the volatile
// state of the key.
//
ASSERT((dwRegOptions == REG_OPTION_VOLATILE) || (dwRegOptions == REG_OPTION_NON_VOLATILE));
if (dwRegOptions & REG_OPTION_VOLATILE) {
dwRegOptions = REG_OPTION_VOLATILE;
} else {
dwRegOptions = REG_OPTION_NON_VOLATILE;
}
//
// Open a key to the parent
//
if (RegOpenKeyEx(
HKEY_LOCAL_MACHINE, pszParentKey, 0,
KEY_ALL_ACCESS, &hParentKey) != ERROR_SUCCESS) {
goto Clean0; // nothing to convert
}
//
// open a key to the child subkey
//
if (RegOpenKeyEx(
hParentKey, pszChildKey, 0,
KEY_ALL_ACCESS, &hChildKey) != ERROR_SUCCESS) {
goto Clean0; // nothing to convert
}
//
// 1. Open a unique temporary key under the special Deleted Key.
// Use the parent key path to form the unique tempory key. There shouldn't
// already be such a key, but if there is then just overwrite it.
//
if (RegOpenKeyEx(
HKEY_LOCAL_MACHINE, pszRegPathCurrentControlSet, 0,
KEY_ALL_ACCESS, &hKey) != ERROR_SUCCESS) {
Status = CR_REGISTRY_ERROR;
goto Clean0;
}
if (FAILED(StringCchPrintf(
RegStr,
SIZECHARS(RegStr),
L"%s\\%s",
pszParentKey,
pszChildKey))) {
Status = CR_FAILURE;
goto Clean0;
}
PathToString(szTempKey, RegStr,MAX_CM_PATH);
if (FAILED(StringCchPrintf(
RegStr,
SIZECHARS(RegStr),
L"%s\\%s",
pszRegKeyDeleted,
szTempKey))) {
Status = CR_FAILURE;
goto Clean0;
}
if (RegCreateKeyEx(
hKey, RegStr, 0, NULL, dwRegOptions,
KEY_ALL_ACCESS, NULL, &hTempKey, NULL) != ERROR_SUCCESS) {
Status = CR_REGISTRY_ERROR;
goto Clean0;
}
//
// 2. Save the current child key (and any subkeys) to a temporary
// location
//
Status = CopyRegistryTree(hChildKey, hTempKey, dwRegOptions);
if (Status != CR_SUCCESS) {
goto CleanupTempKeys;
}
RegCloseKey(hChildKey);
hChildKey = NULL;
//
// 3. Delete the current child key (and any subkeys)
//
if (!RegDeleteNode(hParentKey, pszChildKey)) {
Status = CR_REGISTRY_ERROR;
goto CleanupTempKeys;
}
//
// 4. Recreate the current child key using the volatile state specified
//
if (RegCreateKeyEx(
hParentKey, pszChildKey, 0, NULL,
dwRegOptions, KEY_ALL_ACCESS, NULL,
&hChildKey, NULL) != ERROR_SUCCESS) {
Status = CR_REGISTRY_ERROR;
goto CleanupTempKeys;
}
//
// 5. Copy the original child key (and any subkeys) back
// to the new child key as specified by the volatile state.
//
Status = CopyRegistryTree(hTempKey, hChildKey, dwRegOptions);
if (Status != CR_SUCCESS) {
goto CleanupTempKeys;
}
//
// 6. Remove the temporary instance key (and any subkeys)
//
CleanupTempKeys:
if (hTempKey != NULL) {
RegCloseKey(hTempKey);
hTempKey = NULL;
}
if (SUCCEEDED(StringCchPrintf(
RegStr,
SIZECHARS(RegStr),
L"%s\\%s",
pszRegPathCurrentControlSet,
pszRegKeyDeleted))) {
if (RegOpenKeyEx(
HKEY_LOCAL_MACHINE, RegStr, 0,
KEY_ALL_ACCESS, &hTempKey) == ERROR_SUCCESS) {
RegDeleteNode(hTempKey, szTempKey);
RegCloseKey(hTempKey);
hTempKey = NULL;
}
}
Clean0:
if (hParentKey != NULL) {
RegCloseKey(hParentKey);
}
if (hChildKey != NULL) {
RegCloseKey(hChildKey);
}
if (hKey != NULL) {
RegCloseKey(hKey);
}
if (hTempKey != NULL) {
RegCloseKey(hTempKey);
}
return Status;
} // SetKeyVolatileState
CONFIGRET
MakeKeyVolatile(
IN LPCWSTR pszParentKey,
IN LPCWSTR pszChildKey
)
{
CONFIGRET Status;
//
// Set the state of the key to volatile.
//
Status =
SetKeyVolatileState(
pszParentKey,
pszChildKey,
REG_OPTION_VOLATILE);
return Status;
} // MakeKeyVolatile
CONFIGRET
MakeKeyNonVolatile(
IN LPCWSTR pszParentKey,
IN LPCWSTR pszChildKey
)
{
CONFIGRET Status;
//
// Set the state of the key to non-volatile.
//
Status =
SetKeyVolatileState(
pszParentKey,
pszChildKey,
REG_OPTION_NON_VOLATILE);
return Status;
} // MakeKeyNonVolatile
CONFIGRET
OpenLogConfKey(
IN LPCWSTR pszDeviceID,
IN ULONG LogConfType,
OUT PHKEY phKey
)
{
CONFIGRET Status = CR_SUCCESS;
LONG RegStatus = ERROR_SUCCESS;
HKEY hKey = NULL;
ULONG ulSize = 0;
try {
//
// Open a key to the device ID
//
RegStatus = RegOpenKeyEx(ghEnumKey, pszDeviceID, 0,
KEY_QUERY_VALUE | KEY_SET_VALUE | KEY_CREATE_SUB_KEY,
&hKey);
if (RegStatus != ERROR_SUCCESS) {
Status = CR_INVALID_DEVINST;
goto Clean0;
}
//
// Alloc/Filtered configs are the exception, it's stored in the volative Control
// subkey, all the other log confs are stored under the nonvolatile
// LogConf subkey.
//
if ((LogConfType == ALLOC_LOG_CONF) || (LogConfType == FILTERED_LOG_CONF)) {
//
// Try the control key first, if no alloc config value there,
// then try the log conf key.
//
RegStatus = RegCreateKeyEx(hKey, pszRegKeyDeviceControl, 0, NULL,
REG_OPTION_VOLATILE, KEY_ALL_ACCESS,
NULL, phKey, NULL);
if (RegStatus == ERROR_SUCCESS) {
if (RegQueryValueEx(*phKey, pszRegValueAllocConfig, NULL, NULL,
NULL, &ulSize) == ERROR_SUCCESS) {
goto Clean0;
}
RegCloseKey(*phKey);
}
RegStatus = RegCreateKeyEx(hKey, pszRegKeyLogConf, 0, NULL,
REG_OPTION_NON_VOLATILE, KEY_ALL_ACCESS,
NULL, phKey, NULL);
} else {
RegStatus = RegCreateKeyEx(hKey, pszRegKeyLogConf, 0, NULL,
REG_OPTION_NON_VOLATILE, KEY_ALL_ACCESS,
NULL, phKey, NULL);
}
if (RegStatus != ERROR_SUCCESS) {
Status = CR_REGISTRY_ERROR;
}
Clean0:
NOTHING;
} except(EXCEPTION_EXECUTE_HANDLER) {
Status = CR_FAILURE;
}
if (hKey != NULL) {
RegCloseKey(hKey);
}
return Status;
} // OpenLogConfKey
BOOL
GetActiveService(
IN PCWSTR pszDevice,
OUT PWSTR pszService
)
{
WCHAR RegStr[MAX_CM_PATH];
HKEY hKey = NULL;
ULONG ulSize;
if ((!ARGUMENT_PRESENT(pszService)) ||
(!ARGUMENT_PRESENT(pszDevice))) {
return FALSE;
}
*pszService = TEXT('\0');
//
// open the volatile control key under the device instance
//
if (FAILED(StringCchPrintf(
RegStr,
SIZECHARS(RegStr),
L"%s\\%s\\%s",
pszRegPathEnum,
pszDevice,
pszRegKeyDeviceControl))) {
return FALSE;
}
if (RegOpenKeyEx(HKEY_LOCAL_MACHINE, RegStr, 0, KEY_READ,
&hKey) != ERROR_SUCCESS) {
return FALSE;
}
//
// query the active service value
//
ulSize = MAX_SERVICE_NAME_LEN * sizeof(WCHAR);
if (RegQueryValueEx(hKey, pszRegValueActiveService, NULL, NULL,
(LPBYTE)pszService, &ulSize) != ERROR_SUCCESS) {
RegCloseKey(hKey);
*pszService = TEXT('\0');
return FALSE;
}
RegCloseKey(hKey);
return TRUE;
} // GetActiveService
BOOL
IsDeviceIdPresent(
IN LPCWSTR pszDeviceID
)
/*++
Routine Description:
This routine determines whether the specified device instance is
considered physically present or not. This used to be based on a check
of the old "FoundAtEnum" registry setting. Now we just look for the presense
of an in-memory devnode associated with this device instance to decide whether
it's present or not.
Arguments:
pszDeviceID - device instance string to test for presense on
Return value:
The return value is TRUE if the function suceeds and FALSE if it fails.
--*/
{
ULONG ulStatus, ulProblem;
//
// If the call failed, then assume the device isn't present
//
return GetDeviceStatus(pszDeviceID, &ulStatus, &ulProblem) == CR_SUCCESS;
} // IsDeviceIdPresent
ULONG
GetDeviceConfigFlags(
IN LPCWSTR pszDeviceID,
IN HKEY hKey
)
{
HKEY hDevKey = NULL;
ULONG ulValue = 0, ulSize = sizeof(ULONG);
//
// If hKey is null, then open a key to the device instance.
//
if (hKey == NULL) {
if (RegOpenKeyEx(ghEnumKey, pszDeviceID, 0, KEY_READ,
&hDevKey) != ERROR_SUCCESS) {
goto Clean0;
}
} else {
hDevKey = hKey;
}
//
// Retrieve the configflag value
//
if (RegQueryValueEx(hDevKey, pszRegValueConfigFlags, NULL, NULL,
(LPBYTE)&ulValue, &ulSize) != ERROR_SUCCESS) {
ulValue = 0;
}
Clean0:
if ((hKey == NULL) && (hDevKey != NULL)) {
RegCloseKey(hDevKey);
}
return ulValue;
} // GetDeviceConfigFlags
ULONG
MapNtStatusToCmError(
ULONG NtStatus
)
{
switch (NtStatus) {
case STATUS_BUFFER_TOO_SMALL:
return CR_BUFFER_SMALL;
case STATUS_NO_SUCH_DEVICE:
return CR_NO_SUCH_DEVINST;
case STATUS_INVALID_PARAMETER:
case STATUS_INVALID_PARAMETER_1:
case STATUS_INVALID_PARAMETER_2:
return CR_INVALID_DATA;
case STATUS_NOT_IMPLEMENTED:
return CR_CALL_NOT_IMPLEMENTED;
case STATUS_ACCESS_DENIED:
return CR_ACCESS_DENIED;
case STATUS_OBJECT_NAME_NOT_FOUND:
return CR_NO_SUCH_VALUE;
default:
return CR_FAILURE;
}
} // MapNtStatusToCmError
//
// GUID-related utility routines.
//
BOOL
IsValidGuid(
LPWSTR pszGuid
)
/*++
Routine Description:
This routine determines whether a string is of the proper Guid form.
Arguments:
pszGuid Pointer to a string that will be checked for the standard Guid
format.
Return value:
The return value is TRUE if the string is a valid Guid and FALSE if it
is not.
--*/
{
//----------------------------------------------------------------
// NOTE: This may change later, but for now I am just verifying
// that the string has exactly MAX_GUID_STRING_LEN characters
//----------------------------------------------------------------
if (lstrlen(pszGuid) != MAX_GUID_STRING_LEN-1) {
return FALSE;
}
return TRUE;
} // IsValidGuid
BOOL
GuidEqual(
CONST GUID UNALIGNED *Guid1,
CONST GUID UNALIGNED *Guid2
)
{
RPC_STATUS rpcStatus;
//
// Note - rpcStatus is ignored, the RPC runtime always sets it to RPC_S_OK.
// The UUID comparison result is returned directly, non-zero if the UUIDs
// are equal, zero otherwise.
//
return (BOOL)(UuidEqual((LPGUID)Guid1, (LPGUID)Guid2, &rpcStatus));
} // GuidEqual
DWORD
GuidFromString(
IN PCWSTR GuidString,
OUT LPGUID Guid
)
/*++
Routine Description:
This routine converts the character representation of a GUID into its binary
form (a GUID struct). The GUID is in the following form:
{xxxxxxxx-xxxx-xxxx-xxxx-xxxxxxxxxxxx}
where 'x' is a hexadecimal digit.
Arguments:
GuidString - Supplies a pointer to the null-terminated GUID string. The
Guid - Supplies a pointer to the variable that receives the GUID structure.
Return Value:
If the function succeeds, the return value is NO_ERROR.
If the function fails, the return value is RPC_S_INVALID_STRING_UUID.
--*/
{
WCHAR UuidBuffer[GUID_STRING_LEN - 1];
size_t UuidLen = 0;
//
// Since we're using a RPC UUID routine, we need to strip off the surrounding
// curly braces first.
//
if (*GuidString++ != TEXT('{')) {
return RPC_S_INVALID_STRING_UUID;
}
if (FAILED(StringCchCopy(UuidBuffer,
SIZECHARS(UuidBuffer),
GuidString))) {
return RPC_S_INVALID_STRING_UUID;
}
if (FAILED(StringCchLength(UuidBuffer,
SIZECHARS(UuidBuffer),
&UuidLen))) {
return RPC_S_INVALID_STRING_UUID;
}
if ((UuidLen != GUID_STRING_LEN - 2) ||
(UuidBuffer[GUID_STRING_LEN - 3] != TEXT('}'))) {
return RPC_S_INVALID_STRING_UUID;
}
UuidBuffer[GUID_STRING_LEN - 3] = TEXT('\0');
if (UuidFromString(UuidBuffer, Guid) != RPC_S_OK) {
return RPC_S_INVALID_STRING_UUID;
}
return NO_ERROR;
} // GuidFromString
DWORD
StringFromGuid(
IN CONST GUID *Guid,
OUT PWSTR GuidString,
IN DWORD GuidStringSize
)
/*++
Routine Description:
This routine converts a GUID into a null-terminated string which represents
it. This string is of the form:
{xxxxxxxx-xxxx-xxxx-xxxx-xxxxxxxxxxxx}
where x represents a hexadecimal digit.
This routine comes from ole32\common\ccompapi.cxx. It is included here to avoid linking
to ole32.dll. (The RPC version allocates memory, so it was avoided as well.)
Arguments:
Guid - Supplies a pointer to the GUID whose string representation is
to be retrieved.
GuidString - Supplies a pointer to character buffer that receives the
string. This buffer must be _at least_ 39 (GUID_STRING_LEN) characters
long.
Return Value:
If success, the return value is NO_ERROR.
if failure, the return value is
--*/
{
CONST BYTE *GuidBytes;
INT i;
if(GuidStringSize < GUID_STRING_LEN) {
return ERROR_INSUFFICIENT_BUFFER;
}
GuidBytes = (CONST BYTE *)Guid;
*GuidString++ = TEXT('{');
for(i = 0; i < sizeof(GuidMap); i++) {
if(GuidMap[i] == '-') {
*GuidString++ = TEXT('-');
} else {
*GuidString++ = szDigits[ (GuidBytes[GuidMap[i]] & 0xF0) >> 4 ];
*GuidString++ = szDigits[ (GuidBytes[GuidMap[i]] & 0x0F) ];
}
}
*GuidString++ = TEXT('}');
*GuidString = TEXT('\0');
return NO_ERROR;
} // StringFromGuid