windows-nt/Source/XPSP1/NT/net/upnp/common/upbase/ncreg2.cpp

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//+---------------------------------------------------------------------------
//
// Microsoft Windows
// Copyright (C) Microsoft Corporation, 1997.
//
// File: N C R E G 2 . C P P
//
// Contents: Common routines for dealing with the registry.
//
// Notes:
//
// Author: CWill 27 Mar 1997
//
//----------------------------------------------------------------------------
#include <pch.h>
#pragma hdrstop
#include "ncerror.h"
#include "ncipaddr.h"
#include "ncmem.h"
#include "ncreg.h"
#include "ncstring.h"
#include <regstr.h>
static const WCHAR c_szSubkeyServices[] = REGSTR_PATH_SERVICES;
const struct REG_TYPE_MAP
{
DWORD dwPsuedoType;
DWORD dwType;
};
REG_TYPE_MAP c_rgrtmTypes[] =
{
{REG_BOOL, REG_DWORD},
{REG_IP, REG_SZ},
};
DWORD DwRealTypeFromPsuedoType(const DWORD dwPsuedoType)
{
for (UINT cLoop = 0; cLoop < celems(c_rgrtmTypes); cLoop++)
{
if (dwPsuedoType == c_rgrtmTypes[cLoop].dwPsuedoType)
{
return c_rgrtmTypes[cLoop].dwType;
}
}
return dwPsuedoType;
}
struct SPECIAL_KEY_MAP
{
HKEY hkeyPseudo;
HKEY hkeyRoot;
PCWSTR pszSubKey;
};
static const SPECIAL_KEY_MAP c_rgskmSpec[] =
{
HKLM_SVCS, HKEY_LOCAL_MACHINE, c_szSubkeyServices,
};
//+---------------------------------------------------------------------------
//
// Member: HkeyTrueParent
//
// Purpose: To get a real handle to a key from a pseudo handle
//
// Arguments:
// hkeyIn The pseudo key name
// samDesired The access requested of the key
// rghkeySpec An array of the special keys.
//
// Returns: The handle to the opened key or NULL
//
// Author: CWill Apr 30 1997
//
// Notes:
//
HKEY HkeyTrueParent(const HKEY hkeyIn, const REGSAM samDesired,
HKEY rghkeySpec[])
{
HKEY hkeyRet = hkeyIn;
for (UINT cKey = 0; cKey < celems(c_rgskmSpec); cKey++)
{
// Check arb->hkey for one of "our" well known keys.
if (c_rgskmSpec[cKey].hkeyPseudo == hkeyIn)
{
if (!rghkeySpec[cKey])
{
// First time a special key was used. We need to cache it.
#ifdef DBG
HRESULT hr =
#endif // DBG
HrRegOpenKeyEx(
c_rgskmSpec[cKey].hkeyRoot,
c_rgskmSpec[cKey].pszSubKey,
samDesired,
&rghkeySpec[cKey]);
// If we fail to open the key, make sure the output
// parameter was nulled. This will allow us to proceed
// without really handling the error as hkeyParent
// will be set to null below and the following
// HrRegOpenKey will fail. We will then handle the failure
// of that.
AssertSz(FImplies(FAILED(hr), !rghkeySpec[cKey]), "Key not NULL");
}
hkeyRet = rghkeySpec[cKey];
break;
}
}
return hkeyRet;
}
VOID RegSafeCloseKeyArray(HKEY rghkey[], UINT cElems)
{
for (UINT cKey = 0; cKey < cElems; cKey++)
{
RegSafeCloseKey(rghkey[cKey]);
}
return;
}
//+---------------------------------------------------------------------------
//
// Member: TranslateFromRegToData
//
// Purpose: Translates the data retrieved from the registry to a the user
// data's storage format
//
// Arguments:
// dwType The registry pseudo type that is being translated
// pbData Where the data gets stored
// pbBuf A buffer that stores the registry data
//
// Returns: Nothing.
//
// Author: CWill Apr 30 1997
//
// Notes:
//
VOID TranslateFromRegToData(DWORD dwType, BYTE* pbData, BYTE* pbBuf)
{
// Take the data from the registry and happily convert it into
// usable data
switch (dwType)
{
#ifdef DBG
default:
{
AssertSz(FALSE, "Unknown registry type");
break;
}
#endif // DBG
case REG_IP:
{
// Convert the stringized form of the ip address
// into a DWORD. (The actual 32-bit IP address.)
DWORD dwIpAddr = IpPszToHostAddr((WCHAR*)pbBuf);
*((DWORD*)pbData) = dwIpAddr;
break;
}
case REG_BOOL:
{
// Form the boolean as 'TRUE' or 'FALSE' based on
// whether the data is non-zero or zero respectively.
DWORD dwData = *((DWORD*)pbBuf);
*((BOOL*)pbData) = (!!dwData);
break;
}
case REG_DWORD:
{
// DWORDs are direct assignments
*((DWORD*)pbData) = *((DWORD*)pbBuf);
break;
}
case REG_SZ:
{
// Make a copy of the string
*((PWSTR*) pbData) = SzDupSz((PWSTR)pbBuf);
break;
}
}
return;
}
inline VOID UseDefaultRegValue(DWORD dwType, BYTE* pbData, BYTE* pbDefault)
{
AssertSz((pbData && pbDefault), "UseDefaultRegValue : Invalid params");
AssertSz(pbDefault, "There is no default registry value");
TranslateFromRegToData(dwType, pbData, pbDefault);
return;
}
//+---------------------------------------------------------------------------
//
// Member: CbSizeOfDataToReg
//
// Purpose: To determine the size of buffer needed to store the data
//
// Arguments:
// dwType The registry pseudo type that is being translated
// pbData The data that has to be translated
//
// Returns: The size of buffer need to store the data
//
// Author: CWill Apr 30 1997
//
// Notes:
//
DWORD CbSizeOfDataToReg(DWORD dwType, const BYTE* pbData)
{
DWORD cbData = 0;
switch (dwType)
{
#ifdef DBG
default:
{
AssertSz(FALSE, "Unknown registry type");
break;
}
#endif // DBG
case REG_IP:
{
// Convert the 32-bit IP address to a stringized form.
DWORD dwIpAddr = *((DWORD*)pbData);
WCHAR pszIpAddr [32];
IpHostAddrToPsz(dwIpAddr, pszIpAddr);
cbData = CbOfSzAndTerm(pszIpAddr);
break;
}
// Boolean values are stored as DWORDs
case REG_BOOL:
case REG_DWORD:
{
cbData = sizeof(DWORD);
break;
}
case REG_SZ:
case REG_EXPAND_SZ:
{
cbData = CbOfSzAndTerm(*((PCWSTR*)pbData));
break;
}
}
AssertSz(cbData, "We should have a size");
return cbData;
}
//+---------------------------------------------------------------------------
//
// Member: TranslateFromDataToReg
//
// Purpose: Translates user data to a format the can be stored in the
// registry
//
// Arguments:
// dwType The registry pseudo type that is being translated
// pbData The data that has to be translated
// pbBuf A buffer that stores the registry data
//
// Returns: Nothing.
//
// Author: CWill Apr 30 1997
//
// Notes:
//
VOID
TranslateFromDataToReg(
IN DWORD dwType,
IN const BYTE* pbData,
OUT const BYTE* pbBuf)
{
switch (dwType)
{
#ifdef DBG
default:
{
AssertSz(FALSE, "Unknown registry type");
break;
}
#endif // DBG
case REG_IP:
{
// Convert the 32-bit IP address to a stringized form.
DWORD dwIpAddr = *((DWORD*)pbData);
WCHAR pszIpAddr [32];
IpHostAddrToPsz (dwIpAddr, pszIpAddr);
// Copy the string
lstrcpyW((PWSTR)pbBuf, pszIpAddr);
break;
}
case REG_BOOL:
{
// Form the boolean as 'TRUE' or 'FALSE' based on
// whether the data is non-zero or zero respectively.
DWORD dwData = *((DWORD*)pbData);
*((BOOL*)pbBuf) = (!!dwData);
break;
}
case REG_DWORD:
{
// DWORDs are direct assignments
*((DWORD*)pbBuf) = *((DWORD*)pbData);
break;
}
case REG_SZ:
case REG_EXPAND_SZ:
{
// Make a copy of the string
lstrcpyW((PWSTR)pbBuf, *((PCWSTR*)pbData));
AssertSz(CbOfSzAndTerm(*((PCWSTR*)pbData)), "Zero length string");
break;
}
}
return;
}
//+---------------------------------------------------------------------------
//
// Member: RegReadValues
//
// Purpose: To read a table of information from the registry into a user
// defined data structure.
//
// Arguments:
// crb The count of entries in the REGBATCH structure
// arb The pointer to the REGBATCH structure
// pbUserData The pointer to the source structure that is to retrieve
// the data from the registry
// samDesired The requested key access mask
//
// Returns: Nothing.
//
// Author: CWill Apr 30 1997
//
// Notes:
//
VOID RegReadValues(
IN INT crb,
IN const REGBATCH* arb,
OUT const BYTE* pbUserData,
IN REGSAM samDesired)
{
AssertSz(FImplies(crb, arb), "Count without an array");
HRESULT hr = S_OK;
const REGBATCH* prbLast = NULL;
HKEY rghkeySpec[celems(c_rgskmSpec)] = {0};
HKEY hkey = NULL;
while (crb--)
{
BYTE* pbData = (BYTE*)(pbUserData + arb->cbOffset);
// Open the key if we need to.
// We don't need to if it was the same as the previous one used.
if ((!prbLast )
|| (prbLast->hkey != arb->hkey)
|| (prbLast->pszSubkey != arb->pszSubkey))
{
HKEY hkeyParent;
hkeyParent = HkeyTrueParent (arb->hkey, samDesired, rghkeySpec);
// Close the previous key we used.
RegSafeCloseKey (hkey);
// Open the new key.
#ifdef DBG
hr =
#endif // DBG
HrRegOpenKeyEx (hkeyParent, arb->pszSubkey, samDesired, &hkey);
AssertSz(FImplies(FAILED(hr), !hkey), "HrRegOpenKey not NULLing");
}
// Only continue if we have a key.
if (hkey)
{
DWORD dwType = arb->dwType;
// We can't read NULL registry values
if (REG_CREATE != dwType)
{
DWORD cbData = 0;
BYTE* pbStack = NULL;
DWORD dwRealType = DwRealTypeFromPsuedoType(dwType);
// Ensure that we fail the first time around so that we can see how
// big a buffer is needed
(VOID) HrRegQueryValueEx(hkey, arb->pszValueName, &dwRealType,
NULL, &cbData);
// Allocate memory on the stack to serve as our temporary buffer.
#ifndef STACK_ALLOC_DOESNT_WORK
pbStack = (BYTE*)MemAlloc (cbData);
#else // !STACK_ALLOC_DOESNT_WORK
pbStack = (BYTE*)PvAllocOnStack(cbData);
#endif // !STACK_ALLOC_DOESNT_WORK
hr = HrRegQueryValueEx(hkey, arb->pszValueName, &dwRealType,
pbStack, &cbData);
if (S_OK == hr)
{
// Make sure its the type we were expecting.
AssertSz((dwRealType == DwRealTypeFromPsuedoType(dwType)),
"Value types do no match");
TranslateFromRegToData(dwType, pbData, pbStack);
}
else
{
UseDefaultRegValue(dwType, pbData, arb->pbDefault);
TraceHr (ttidError, FAL, hr,
HRESULT_FROM_WIN32(ERROR_FILE_NOT_FOUND) == hr,
"RegReadValues: Could not open value %S", arb->pszValueName);
}
#ifndef STACK_ALLOC_DOESNT_WORK
MemFree (pbStack);
#endif // STACK_ALLOC_DOESNT_WORK
}
}
else
{
TraceTag(ttidError, "RegReadValues: NULL key for %S", arb->pszSubkey);
UseDefaultRegValue(arb->dwType, pbData, arb->pbDefault);
}
// Advance prbLast or set it to the first one if this is the
// first time through.
if (prbLast)
{
prbLast++;
}
else
{
prbLast = arb;
}
arb++;
}
// Clean up
RegSafeCloseKey(hkey);
RegSafeCloseKeyArray(rghkeySpec, celems(rghkeySpec));
return;
}
//+---------------------------------------------------------------------------
//
// Member: HrRegWriteValues
//
// Purpose: To write a table of information to the registry from a user
// defined data structure.
//
// Arguments:
// crb The count of entries in the REGBATCH structure
// arb The pointer to the REGBATCH structure
// pbUserData The pointer to the source structure that provides
// the data that is to be written to the registry
// dwOptions Options to be used when creating the registry keys
// samDesired The requested key access mask
//
// Returns: S_OK or an HRESULT_FROM_WIN32 error code.
//
// Author: CWill Apr 30 1997
//
// Notes:
//
HRESULT HrRegWriteValues(
INT crb,
const REGBATCH* arb,
const BYTE* pbUserData,
DWORD dwOptions,
REGSAM samDesired)
{
AssertSz(FImplies(crb, arb), "HrWriteValues : Count with no array");
HRESULT hr = S_OK;
const REGBATCH* prbLast = NULL;
HKEY hkey = NULL;
HKEY rghkeySpec[celems(c_rgskmSpec)] = {0};
while (crb--)
{
BYTE* pbData = const_cast<BYTE*>(pbUserData + arb->cbOffset);
// Open the key if we need to.
// We don't need to if it was the same as the previous one used.
if ((!prbLast)
|| (prbLast->hkey != arb->hkey)
|| (prbLast->pszSubkey != arb->pszSubkey))
{
HKEY hkeyParent;
hkeyParent = HkeyTrueParent(arb->hkey, samDesired, rghkeySpec);
// Close the previous key we used.
RegSafeCloseKey(hkey);
// Open the new key.
DWORD dwDisposition;
hr = HrRegCreateKeyEx(hkeyParent, arb->pszSubkey, dwOptions,
samDesired, NULL, &hkey, &dwDisposition);
AssertSz(FImplies(FAILED(hr), !hkey), "HrRegCreateKey not NULLing");
if (FAILED(hr))
{
TraceError("HrRegWriteValues: failed to open parent key", hr);
break;
}
}
// Should definately have hkey by now.
AssertSz(hkey, "Why no key?");
//
// Format the data to be put into the registry
//
DWORD dwType = arb->dwType;
// If all we want to do is create the key, then we are already done.
if (REG_CREATE != dwType)
{
DWORD dwRealType = DwRealTypeFromPsuedoType(dwType);
DWORD cbReg = CbSizeOfDataToReg(dwType, pbData);
BYTE* pbReg = NULL;
AssertSz(cbReg, "We must have some data");
#ifndef STACK_ALLOC_DOESNT_WORK
pbReg = new BYTE[cbReg];
#else // !STACK_ALLOC_DOESNT_WORK
pbReg = reinterpret_cast<BYTE*>(PvAllocOnStack(cbReg));
#endif // !STACK_ALLOC_DOESNT_WORK
TranslateFromDataToReg(dwType, pbData, pbReg);
// Write the data to the registry.
hr = HrRegSetValueEx(
hkey,
arb->pszValueName,
dwRealType,
pbReg,
cbReg);
#ifndef STACK_ALLOC_DOESNT_WORK
// Must have this call before the break
delete [] pbReg;
#endif // STACK_ALLOC_DOESNT_WORK
}
if (FAILED(hr))
{
break;
}
// Advance prbLast or set it to the first one if this is the
// first time through.
if (prbLast)
{
prbLast++;
}
else
{
prbLast = arb;
}
arb++;
}
RegSafeCloseKey(hkey);
RegSafeCloseKeyArray(rghkeySpec, celems(rghkeySpec));
TraceError("HrWriteValues", hr);
return hr;
}
//+---------------------------------------------------------------------------
//
// Member: HrRegWriteValueTable
//
// Purpose: To write a table of values to the registry from a user
// defined data structure.
//
// Arguments:
// hkeyRoot The key to which the values are written
// cvt The count of entries in the VALUETABLE structure
// avt The pointer to the VALUETABLE structure
// pbUserData The pointer to the source structure that provides
// the data that is to be written to the registry
// dwOptions Options to be used when creating the registry keys
// samDesired The requested key access mask
//
// Returns: S_OK or an HRESULT_FROM_WIN32 error code.
//
// Author: CWill 06/26/97
//
// Notes:
//
HRESULT HrRegWriteValueTable(
HKEY hkeyRoot,
INT cvt,
const VALUETABLE* avt,
const BYTE* pbUserData,
DWORD dwOptions,
REGSAM samDesired)
{
HRESULT hr = S_OK;
while (cvt--)
{
BYTE* pbData = NULL;
DWORD dwType = REG_NONE;
//
// Format the data to be put into the registry
//
dwType = avt->dwType;
pbData = const_cast<BYTE*>(pbUserData + avt->cbOffset);
// If all we want to do is create the key, then we are already done.
if (REG_CREATE != dwType)
{
DWORD dwRealType = DwRealTypeFromPsuedoType(dwType);
DWORD cbReg = CbSizeOfDataToReg(dwType, pbData);
BYTE* pbReg = NULL;
AssertSz(cbReg, "We must have some data");
#ifndef STACK_ALLOC_DOESNT_WORK
pbReg = new BYTE[cbReg];
#else // !STACK_ALLOC_DOESNT_WORK
pbReg = reinterpret_cast<BYTE*>(PvAllocOnStack(cbReg));
#endif // !STACK_ALLOC_DOESNT_WORK
TranslateFromDataToReg(dwType, pbData, pbReg);
// Write the data to the registry.
hr = HrRegSetValueEx(
hkeyRoot,
avt->pszValueName,
dwRealType,
pbReg,
cbReg);
#ifndef STACK_ALLOC_DOESNT_WORK
// Must have this call before the break
delete [] pbReg;
#endif // STACK_ALLOC_DOESNT_WORK
}
if (FAILED(hr))
{
break;
}
avt++;
}
TraceError("HrRegWriteValueTable", hr);
return hr;
}