WindowsXP-SP1/base/pnp/lib/cutil.c

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2001-01-01 00:00:00 +01:00
/*++
Copyright (c) 1995-2001 Microsoft Corporation
Module Name:
cutil.c
Abstract:
This module contains general utility routines used by both cfgmgr32
and umpnpmgr.
IsLegalDeviceId
SplitDeviceInstanceString
DeletePrivateKey
RegDeleteNode
Split1
Split2
GetDevNodeKeyPath
MapRpcExceptionToCR
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"
#include "umpnplib.h"
//
// Common private utility routines (used by client and server)
//
BOOL
IsLegalDeviceId(
IN LPCWSTR pszDeviceInstance
)
/*++
Routine Description:
This routine parses the device instance string and validates whether it
conforms to the appropriate rules, including:
- Total length of the device instance path must not be longer than
MAX_DEVICE_ID_LEN characters.
- The device instance path must contain exactly 3 non-empty path components.
- The device instance path string must not contain any "invalid characters".
Invalid characters are:
c <= 0x20 (' ')
c > 0x7F
c == 0x2C (',')
Arguments:
pszDeviceInstance - Device instance path.
Return value:
The return value is TRUE if the device instance path string conforms to the
rules.
--*/
{
BOOL Status;
LPCWSTR p;
ULONG ulTotalLength = 0;
ULONG ulComponentLength = 0, ulComponents = 1;
try {
//
// An empty string is used for an optional device instance path.
//
if ((pszDeviceInstance == NULL) || (*pszDeviceInstance == L'\0')) {
Status = TRUE;
goto Clean0;
}
//
// Walk over the entire device instance path, counting the total length,
// individual path component lengths, and checking for the presence of
// invalid characters.
//
for (p = pszDeviceInstance; *p; p++) {
//
// Make sure the device instance path isn't too long.
//
ulTotalLength++;
if (ulTotalLength > MAX_DEVICE_ID_LEN) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: IsLegalDeviceId: "
"device instance path %ws longer than "
"MAX_DEVICE_ID_LEN characters!\n",
pszDeviceInstance));
//ASSERT(ulTotalLength <= MAX_DEVICE_ID_LEN);
Status = FALSE;
goto Clean0;
}
//
// Check for the presence of invalid characters.
//
if ((*p <= L' ') || (*p > (WCHAR)0x7F) || (*p == L',')) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: IsLegalDeviceId: "
"device instance path %ws contains invalid character (0x%lx)!\n",
pszDeviceInstance, *p));
//ASSERT((*p > L' ') && (*p <= (WCHAR)0x7F) && (*p != L','));
Status = FALSE;
goto Clean0;
}
//
// Check the length of individual path components.
//
if (*p == L'\\') {
//
// It is illegal for a device instance path to have multiple
// consecutive path separators, or to start with one.
//
if (ulComponentLength == 0) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: IsLegalDeviceId: "
"device instance path %ws contains "
"invalid path component!\n",
pszDeviceInstance));
//ASSERT(ulComponentLength != 0);
Status = FALSE;
goto Clean0;
}
ulComponentLength = 0;
ulComponents++;
} else {
//
// Count the length of this path component to verify it's not empty.
//
ulComponentLength++;
}
}
//
// It is illegal for a device instance path to end with a path separator
// character.
//
if (ulComponentLength == 0) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: IsLegalDeviceId: "
"device instance path %ws has trailing '\\' char!\n",
pszDeviceInstance));
//ASSERT(ulComponentLength != 0);
Status = FALSE;
goto Clean0;
}
//
// A valid device instance path must contain exactly 3 path components:
// an enumerator id, a device id, and an instance id.
//
if (ulComponents != 3) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: IsLegalDeviceId: "
"device instance path %ws contains "
"invalid number of path components!\n",
pszDeviceInstance));
//ASSERT(ulComponents == 3);
Status = FALSE;
goto Clean0;
}
Status = TRUE;
Clean0:
NOTHING;
} except(EXCEPTION_EXECUTE_HANDLER) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP: Exception in IsLegalDeviceId!! "
"exception code = %d\n",
GetExceptionCode()));
Status = FALSE;
}
return Status;
} // IsLegalDeviceId
BOOL
SplitDeviceInstanceString(
IN LPCWSTR pszDeviceInstance,
OUT LPWSTR pszBase,
OUT LPWSTR pszDeviceID,
OUT LPWSTR pszInstanceID
)
/*++
Routine Description:
This routine parses a device instance string into it's three component
parts. Since this is an internal routine, NO error checking is done on
the pszBase, pszDeviceID, and pszInstanceID routines; I always assume that
valid pointers are passed in and that each of these buffers is at least
MAX_DEVICE_ID_LEN characters in length. I do some error checking on the
pszDeviceInstance string since it is passed in from the client side.
Arguments:
Return value:
The return value is TRUE if the function suceeds and FALSE if it fails.
--*/
{
UINT ulLength, i, j;
ulLength = lstrlen(pszDeviceInstance);
//
// parse the string for the first backslash character
//
for (i=0; i < ulLength && pszDeviceInstance[i] != '\0' &&
pszDeviceInstance[i] != '\\'; i++);
if (pszDeviceInstance[i] != '\\') {
lstrcpyn(pszBase, pszDeviceInstance,MAX_DEVICE_ID_LEN);
*pszDeviceID = '\0';
*pszInstanceID = '\0';
return FALSE; // not a complete device instance string
}
i++; // increment past the backslash character
if (i < ulLength && pszDeviceInstance[i] != '\0') {
lstrcpyn(pszBase, pszDeviceInstance, min(i,MAX_DEVICE_ID_LEN));
}
else {
*pszBase = '\0';
*pszDeviceID = '\0';
*pszInstanceID = '\0';
return FALSE;
}
//
// parse the string for second backslash character
//
for (j=i; j < ulLength && pszDeviceInstance[j] != '\0' &&
pszDeviceInstance[j] != '\\'; j++);
if (pszDeviceInstance[j] != '\\' || j > ulLength) {
lstrcpyn(pszDeviceID, &pszDeviceInstance[i],MAX_DEVICE_ID_LEN);
*pszInstanceID = '\0';
return FALSE;
}
j++;
lstrcpyn(pszDeviceID, &pszDeviceInstance[i], min(j-i,MAX_DEVICE_ID_LEN));
lstrcpyn(pszInstanceID, &pszDeviceInstance[j], min((ulLength-j+1),MAX_DEVICE_ID_LEN));
return TRUE;
} // SplitDeviceInstanceString
CONFIGRET
DeletePrivateKey(
IN HKEY hBranchKey,
IN LPCWSTR pszParentKey,
IN LPCWSTR pszChildKey
)
{
CONFIGRET Status = CR_SUCCESS;
LONG RegStatus = ERROR_SUCCESS;
WCHAR RegStr[2*MAX_CM_PATH],
szKey1[MAX_CM_PATH],
szKey2[MAX_CM_PATH];
HKEY hKey = NULL;
ULONG ulSubKeys = 0;
//
// Make sure the specified registry key paths are valid.
//
if ((pszParentKey == NULL) ||
(pszChildKey == NULL) ||
((lstrlen(pszParentKey) + 1) > MAX_CM_PATH) ||
((lstrlen(pszChildKey) + 1) > MAX_CM_PATH)) {
Status = CR_INVALID_POINTER;
goto Clean0;
}
//
// is the specified child key a compound registry key?
//
if (!Split1(pszChildKey, szKey1, szKey2)) {
//------------------------------------------------------------------
// Only a single child key was specified, so just open the parent
// registry key and delete the child (and any of its subkeys)
//------------------------------------------------------------------
if (RegOpenKeyEx(hBranchKey, pszParentKey, 0,
KEY_READ | KEY_WRITE, &hKey) != ERROR_SUCCESS) {
goto Clean0; // no error, nothing to delete
}
if (!RegDeleteNode(hKey, pszChildKey)) {
Status = CR_REGISTRY_ERROR;
goto Clean0;
}
}
else {
//------------------------------------------------------------------
// if a compound registry path was passed in, such as key1\key2
// then always delete key2 but delete key1 only if it has no other
// subkeys besides key2.
//------------------------------------------------------------------
//
// open the first level key
//
wsprintf(RegStr, TEXT("%s\\%s"),
pszParentKey,
szKey1);
RegStatus = RegOpenKeyEx(
hBranchKey, RegStr, 0, KEY_QUERY_VALUE | KEY_SET_VALUE,
&hKey);
if (RegStatus != ERROR_SUCCESS) {
goto Clean0; // no error, nothing to delete
}
//
// try to delete the second level key
//
if (!RegDeleteNode(hKey, szKey2)) {
goto Clean0; // no error, nothing to delete
}
//
// How many subkeys are remaining?
//
RegStatus = RegQueryInfoKey(
hKey, NULL, NULL, NULL, &ulSubKeys,
NULL, NULL, NULL, NULL, NULL, NULL, NULL);
if (RegStatus != ERROR_SUCCESS) {
goto Clean0; // nothing to delete
}
//
// if no more subkeys, then delete the first level key
//
if (ulSubKeys == 0) {
RegCloseKey(hKey);
hKey = NULL;
RegStatus = RegOpenKeyEx(
hBranchKey, pszParentKey, 0,
KEY_QUERY_VALUE | KEY_SET_VALUE, &hKey);
if (RegStatus != ERROR_SUCCESS) {
goto Clean0; // no error, nothing to delete
}
if (!RegDeleteNode(hKey, szKey1)) {
Status = CR_REGISTRY_ERROR;
goto Clean0;
}
}
}
Clean0:
if (hKey != NULL) {
RegCloseKey(hKey);
}
return Status;
} // DeletePrivateKey
BOOL
RegDeleteNode(
HKEY hParentKey,
LPCWSTR szKey
)
{
ULONG ulSize = 0;
LONG RegStatus = ERROR_SUCCESS;
HKEY hKey = NULL;
WCHAR szSubKey[MAX_PATH];
//
// attempt to delete the key
//
if (RegDeleteKey(hParentKey, szKey) != ERROR_SUCCESS) {
RegStatus = RegOpenKeyEx(
hParentKey, szKey, 0, KEY_ALL_ACCESS, &hKey);
//
// enumerate subkeys and delete those nodes
//
while (RegStatus == ERROR_SUCCESS) {
//
// enumerate the first level children under the profile key
// (always use index 0, enumeration looses track when a key
// is added or deleted)
//
ulSize = MAX_PATH;
RegStatus = RegEnumKeyEx(
hKey, 0, szSubKey, &ulSize, NULL, NULL, NULL, NULL);
if (RegStatus == ERROR_SUCCESS) {
RegDeleteNode(hKey, szSubKey);
}
}
//
// either an error occured that prevents me from deleting the
// keys (like the key doesn't exist in the first place or an
// access violation) or the subkeys have been deleted, try
// deleting the top level key again
//
RegCloseKey(hKey);
RegDeleteKey(hParentKey, szKey);
}
return TRUE;
} // RegDeleteNode
BOOL
Split1(
IN LPCWSTR pszString,
OUT LPWSTR pszString1,
OUT LPWSTR pszString2
)
{
BOOL Status = TRUE;
LPWSTR p;
//
// Split the string at the first backslash character
//
try {
lstrcpy(pszString1, pszString);
for (p = pszString1; (*p) && (*p != TEXT('\\')); p++);
if (*p == TEXT('\0')) {
Status = FALSE;
goto Clean0;
}
*p = TEXT('\0'); // truncate string1
p++;
lstrcpy(pszString2, p); // the rest is string2
Clean0:
NOTHING;
} except(EXCEPTION_EXECUTE_HANDLER) {
Status = FALSE;
}
return Status;
} // Split1
BOOL
Split2(
IN LPCWSTR pszString,
OUT LPWSTR pszString1,
OUT LPWSTR pszString2
)
{
BOOL Status = TRUE;
LPWSTR p;
//
// Split the string at the second backslash character
//
try {
lstrcpy(pszString1, pszString);
for (p = pszString1; (*p) && (*p != TEXT('\\')); p++); // first
for (p++; (*p) && (*p != TEXT('\\')); p++); // second
*p = TEXT('\0'); // truncate string1
p++;
lstrcpy(pszString2, p); // the rest is string2
} except(EXCEPTION_EXECUTE_HANDLER) {
Status = FALSE;
}
return Status;
} // Split2
CONFIGRET
GetDevNodeKeyPath(
IN handle_t hBinding,
IN LPCWSTR pDeviceID,
IN ULONG ulFlags,
IN ULONG ulHardwareProfile,
OUT LPWSTR pszBaseKey,
OUT LPWSTR pszPrivateKey
)
{
CONFIGRET Status = CR_SUCCESS;
WCHAR szClassInstance[MAX_PATH], szEnumerator[MAX_DEVICE_ID_LEN];
ULONG ulSize, ulDataType = 0;
ULONG ulTransferLen;
//-------------------------------------------------------------
// form the key for the software branch case
//-------------------------------------------------------------
if (ulFlags & CM_REGISTRY_SOFTWARE) {
//
// retrieve the class name and instance ordinal by calling
// the server's reg prop routine
//
ulSize = ulTransferLen = sizeof(szClassInstance);
RpcTryExcept {
Status = PNP_GetDeviceRegProp(
hBinding,
pDeviceID,
CM_DRP_DRIVER,
&ulDataType,
(LPBYTE)szClassInstance,
&ulTransferLen,
&ulSize,
0);
}
RpcExcept (I_RpcExceptionFilter(RpcExceptionCode())) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP_GetDeviceRegProp caused an exception (%d)\n",
RpcExceptionCode()));
Status = MapRpcExceptionToCR(RpcExceptionCode());
}
RpcEndExcept
if (Status != CR_SUCCESS || *szClassInstance == '\0') {
//
// no Driver (class instance) value yet so ask the server to
// create a new unique one
//
ulSize = sizeof(szClassInstance);
RpcTryExcept {
Status = PNP_GetClassInstance(
hBinding,
pDeviceID,
szClassInstance,
ulSize);
}
RpcExcept (I_RpcExceptionFilter(RpcExceptionCode())) {
KdPrintEx((DPFLTR_PNPMGR_ID,
DBGF_ERRORS,
"PNP_GetClassInstance caused an exception (%d)\n",
RpcExceptionCode()));
Status = MapRpcExceptionToCR(RpcExceptionCode());
}
RpcEndExcept
if (Status != CR_SUCCESS) {
goto Clean0;
}
}
//
// the <instance> part of the class instance is the private part
//
Split1(szClassInstance, szClassInstance, pszPrivateKey);
//
// config-specific software branch case
//
if (ulFlags & CM_REGISTRY_CONFIG) {
//
// curent config
//
// System\CCC\Hardware Profiles\Current
// \System\CCC\Control\Class\<DevNodeClassInstance>
//
if (ulHardwareProfile == 0) {
wsprintf(pszBaseKey, TEXT("%s\\%s\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
REGSTR_KEY_CURRENT,
REGSTR_PATH_CLASS_NT,
szClassInstance);
}
//
// all configs, use substitute string for profile id
//
else if (ulHardwareProfile == 0xFFFFFFFF) {
wsprintf(pszBaseKey, TEXT("%s\\%s\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
TEXT("%s"),
REGSTR_PATH_CLASS_NT,
szClassInstance);
}
//
// specific profile specified
//
// System\CCC\Hardware Profiles\<profile>
// \System\CCC\Control\Class\<DevNodeClassInstance>
//
else {
wsprintf(pszBaseKey, TEXT("%s\\%04u\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
ulHardwareProfile,
REGSTR_PATH_CLASS_NT,
szClassInstance);
}
}
//
// not config-specific
// System\CCC\Control\Class\<DevNodeClassInstance>
//
else {
wsprintf(pszBaseKey, TEXT("%s\\%s"),
REGSTR_PATH_CLASS_NT,
szClassInstance);
}
}
//-------------------------------------------------------------
// form the key for the hardware branch case
//-------------------------------------------------------------
else {
//
// config-specific hardware branch case
//
if (ulFlags & CM_REGISTRY_CONFIG) {
//
// for profile specific, the <device>\<instance> part of
// the device id is the private part
//
Split1(pDeviceID, szEnumerator, pszPrivateKey);
//
// curent config
//
if (ulHardwareProfile == 0) {
wsprintf(pszBaseKey, TEXT("%s\\%s\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
REGSTR_KEY_CURRENT,
REGSTR_PATH_SYSTEMENUM,
szEnumerator);
}
//
// all configs, use replacement symbol for profile id
//
else if (ulHardwareProfile == 0xFFFFFFFF) {
wsprintf(pszBaseKey, TEXT("%s\\%s\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
TEXT("%s"),
REGSTR_PATH_SYSTEMENUM,
szEnumerator);
}
//
// specific profile specified
//
else {
wsprintf(pszBaseKey, TEXT("%s\\%04u\\%s\\%s"),
REGSTR_PATH_HWPROFILES,
ulHardwareProfile,
REGSTR_PATH_SYSTEMENUM,
szEnumerator);
}
}
else if (ulFlags & CM_REGISTRY_USER) {
//
// for hardware user key, the <device>\<instance> part of
// the device id is the private part
//
Split1(pDeviceID, szEnumerator, pszPrivateKey);
wsprintf(pszBaseKey, TEXT("%s\\%s"),
REGSTR_PATH_SYSTEMENUM,
szEnumerator);
}
//
// not config-specific
//
else {
wsprintf(pszBaseKey, TEXT("%s\\%s"),
REGSTR_PATH_SYSTEMENUM,
pDeviceID);
lstrcpy(pszPrivateKey, REGSTR_KEY_DEVICEPARAMETERS);
}
}
Clean0:
return Status;
} // GetDevNodeKeyPath
CONFIGRET
MapRpcExceptionToCR(
ULONG ulRpcExceptionCode
)
/*++
Routine Description:
This routine takes an rpc exception code (typically received by
calling RpcExceptionCode) and returns a corresponding CR_ error
code.
Arguments:
ulRpcExceptionCode An RPC_S_ or RPC_X_ exception error code.
Return Value:
Return value is one of the CR_ error codes.
--*/
{
CONFIGRET Status = CR_FAILURE;
switch(ulRpcExceptionCode) {
//
// binding or machine name errors
//
case RPC_S_INVALID_STRING_BINDING: // 1700L
case RPC_S_WRONG_KIND_OF_BINDING: // 1701L
case RPC_S_INVALID_BINDING: // 1702L
case RPC_S_PROTSEQ_NOT_SUPPORTED: // 1703L
case RPC_S_INVALID_RPC_PROTSEQ: // 1704L
case RPC_S_INVALID_STRING_UUID: // 1705L
case RPC_S_INVALID_ENDPOINT_FORMAT: // 1706L
case RPC_S_INVALID_NET_ADDR: // 1707L
case RPC_S_NO_ENDPOINT_FOUND: // 1708L
case RPC_S_NO_MORE_BINDINGS: // 1806L
case RPC_S_CANT_CREATE_ENDPOINT: // 1720L
Status = CR_INVALID_MACHINENAME;
break;
//
// general rpc communication failure
//
case RPC_S_INVALID_NETWORK_OPTIONS: // 1724L
case RPC_S_CALL_FAILED: // 1726L
case RPC_S_CALL_FAILED_DNE: // 1727L
case RPC_S_PROTOCOL_ERROR: // 1728L
case RPC_S_UNSUPPORTED_TRANS_SYN: // 1730L
Status = CR_REMOTE_COMM_FAILURE;
break;
//
// couldn't make connection to that machine
//
case RPC_S_SERVER_UNAVAILABLE: // 1722L
case RPC_S_SERVER_TOO_BUSY: // 1723L
Status = CR_MACHINE_UNAVAILABLE;
break;
//
// server doesn't exist or not right version
//
case RPC_S_INVALID_VERS_OPTION: // 1756L
case RPC_S_INTERFACE_NOT_FOUND: // 1759L
case RPC_S_UNKNOWN_IF: // 1717L
Status = CR_NO_CM_SERVICES;
break;
//
// any other RPC exceptions will just be general failures
//
default:
Status = CR_FAILURE;
break;
}
return Status;
} // MapRpcExceptionToCR