windows-nt/Source/XPSP1/NT/termsrv/license/lrwizapi/utils.cpp

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2020-09-26 03:20:57 -05:00
//Copyright (c) 1998 - 1999 Microsoft Corporation
//
//This file contains wrapper C functions for CGlobal Object
//
#include "precomp.h"
#include "utils.h"
#ifndef TLSPERF
#include "global.h"
extern CGlobal *g_CGlobal;
#else
#include "globalPerf.h"
extern CGlobalPerf *g_CGlobal;
#endif
#include "assert.h"
// The following table translates an ascii subset to 6 bit values as follows
// (see rfc 1521):
//
// input hex (decimal)
// 'A' --> 0x00 (0)
// 'B' --> 0x01 (1)
// ...
// 'Z' --> 0x19 (25)
// 'a' --> 0x1a (26)
// 'b' --> 0x1b (27)
// ...
// 'z' --> 0x33 (51)
// '0' --> 0x34 (52)
// ...
// '9' --> 0x3d (61)
// '+' --> 0x3e (62)
// '/' --> 0x3f (63)
//
// Encoded lines must be no longer than 76 characters.
// The final "quantum" is handled as follows: The translation output shall
// always consist of 4 characters. 'x', below, means a translated character,
// and '=' means an equal sign. 0, 1 or 2 equal signs padding out a four byte
// translation quantum means decoding the four bytes would result in 3, 2 or 1
// unencoded bytes, respectively.
//
// unencoded size encoded data
// -------------- ------------
// 1 byte "xx=="
// 2 bytes "xxx="
// 3 bytes "xxxx"
#define CB_BASE64LINEMAX 64 // others use 64 -- could be up to 76
// Any other (invalid) input character value translates to 0x40 (64)
const BYTE abDecode[256] =
{
/* 00: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* 10: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* 20: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 62, 64, 64, 64, 63,
/* 30: */ 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 64, 64, 64, 64, 64, 64,
/* 40: */ 64, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14,
/* 50: */ 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 64, 64, 64, 64, 64,
/* 60: */ 64, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40,
/* 70: */ 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 64, 64, 64, 64, 64,
/* 80: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* 90: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* a0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* b0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* c0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* d0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* e0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
/* f0: */ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
};
const UCHAR abEncode[] =
/* 0 thru 25: */ "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
/* 26 thru 51: */ "abcdefghijklmnopqrstuvwxyz"
/* 52 thru 61: */ "0123456789"
/* 62 and 63: */ "+/";
DWORD LSBase64EncodeA(
IN BYTE const *pbIn,
IN DWORD cbIn,
OUT CHAR *pchOut,
OUT DWORD *pcchOut)
{
CHAR *pchOutT;
DWORD cchOutEncode;
// Allocate enough memory for full final translation quantum.
cchOutEncode = ((cbIn + 2) / 3) * 4;
// and enough for CR-LF pairs for every CB_BASE64LINEMAX character line.
cchOutEncode +=
2 * ((cchOutEncode + CB_BASE64LINEMAX - 1) / CB_BASE64LINEMAX);
pchOutT = pchOut;
if (NULL == pchOut)
{
pchOutT += cchOutEncode;
}
else
{
DWORD cCol;
assert(cchOutEncode <= *pcchOut);
cCol = 0;
while ((long) cbIn > 0) // signed comparison -- cbIn can wrap
{
BYTE ab3[3];
if (cCol == CB_BASE64LINEMAX/4)
{
cCol = 0;
*pchOutT++ = '\r';
*pchOutT++ = '\n';
}
cCol++;
memset(ab3, 0, sizeof(ab3));
ab3[0] = *pbIn++;
if (cbIn > 1)
{
ab3[1] = *pbIn++;
if (cbIn > 2)
{
ab3[2] = *pbIn++;
}
}
*pchOutT++ = abEncode[ab3[0] >> 2];
*pchOutT++ = abEncode[((ab3[0] << 4) | (ab3[1] >> 4)) & 0x3f];
*pchOutT++ = (cbIn > 1)?
abEncode[((ab3[1] << 2) | (ab3[2] >> 6)) & 0x3f] : '=';
*pchOutT++ = (cbIn > 2)? abEncode[ab3[2] & 0x3f] : '=';
cbIn -= 3;
}
*pchOutT++ = '\r';
*pchOutT++ = '\n';
assert((DWORD) (pchOutT - pchOut) <= cchOutEncode);
}
*pcchOut = (DWORD)(pchOutT - pchOut);
return(ERROR_SUCCESS);
}
DWORD LSBase64DecodeA(
IN CHAR const *pchIn,
IN DWORD cchIn,
OUT BYTE *pbOut,
OUT DWORD *pcbOut)
{
DWORD err = ERROR_SUCCESS;
DWORD cchInDecode, cbOutDecode;
CHAR const *pchInEnd;
CHAR const *pchInT;
BYTE *pbOutT;
// Count the translatable characters, skipping whitespace & CR-LF chars.
cchInDecode = 0;
pchInEnd = &pchIn[cchIn];
for (pchInT = pchIn; pchInT < pchInEnd; pchInT++)
{
if (sizeof(abDecode) < (unsigned) *pchInT || abDecode[*pchInT] > 63)
{
// skip all whitespace
if (*pchInT == ' ' ||
*pchInT == '\t' ||
*pchInT == '\r' ||
*pchInT == '\n')
{
continue;
}
if (0 != cchInDecode)
{
if ((cchInDecode % 4) == 0)
{
break; // ends on quantum boundary
}
// The length calculation may stop in the middle of the last
// translation quantum, because the equal sign padding
// characters are treated as invalid input. If the last
// translation quantum is not 4 bytes long, it must be 2 or 3
// bytes long.
if (*pchInT == '=' && (cchInDecode % 4) != 1)
{
break; // normal termination
}
}
err = ERROR_INVALID_DATA;
goto error;
}
cchInDecode++;
}
assert(pchInT <= pchInEnd);
pchInEnd = pchInT; // don't process any trailing stuff again
// We know how many translatable characters are in the input buffer, so now
// set the output buffer size to three bytes for every four (or fraction of
// four) input bytes.
cbOutDecode = ((cchInDecode + 3) / 4) * 3;
pbOutT = pbOut;
if (NULL == pbOut)
{
pbOutT += cbOutDecode;
}
else
{
// Decode one quantum at a time: 4 bytes ==> 3 bytes
assert(cbOutDecode <= *pcbOut);
pchInT = pchIn;
while (cchInDecode > 0)
{
DWORD i;
BYTE ab4[4];
memset(ab4, 0, sizeof(ab4));
for (i = 0; i < min(sizeof(ab4)/sizeof(ab4[0]), cchInDecode); i++)
{
while (
sizeof(abDecode) > (unsigned) *pchInT &&
63 < abDecode[*pchInT])
{
pchInT++;
}
assert(pchInT < pchInEnd);
ab4[i] = (BYTE) *pchInT++;
}
// Translate 4 input characters into 6 bits each, and deposit the
// resulting 24 bits into 3 output bytes by shifting as appropriate.
// out[0] = in[0]:in[1] 6:2
// out[1] = in[1]:in[2] 4:4
// out[2] = in[2]:in[3] 2:6
*pbOutT++ =
(BYTE) ((abDecode[ab4[0]] << 2) | (abDecode[ab4[1]] >> 4));
if (i > 2)
{
*pbOutT++ =
(BYTE) ((abDecode[ab4[1]] << 4) | (abDecode[ab4[2]] >> 2));
}
if (i > 3)
{
*pbOutT++ = (BYTE) ((abDecode[ab4[2]] << 6) | abDecode[ab4[3]]);
}
cchInDecode -= i;
}
assert((DWORD) (pbOutT - pbOut) <= cbOutDecode);
}
*pcbOut = (DWORD)(pbOutT - pbOut);
error:
return(err);
}
#ifndef TLSPERF
CGlobal * GetGlobalContext(void)
#else
CGlobalPerf * GetGlobalContext(void)
#endif
{
return g_CGlobal;
}
DWORD WINAPI ProcessThread(void *pData)
{
DWORD dwRetCode = ERROR_SUCCESS;
dwRetCode = ProcessRequest();
/*
DWORD dwTime = 1;
HWND *phProgress = (HWND *)pData;
SendMessage(g_hProgressWnd, PBM_SETRANGE, 0, MAKELPARAM(0,PROGRESS_MAX_VAL));
//
// Increment the progress bar every second till you get Progress Event
//
SendMessage(g_hProgressWnd, PBM_SETPOS ,(WPARAM)1, 0);
do
{
SendMessage(g_hProgressWnd, PBM_DELTAPOS ,(WPARAM)PROGRESS_STEP_VAL, 0);
}
while(WAIT_TIMEOUT == WaitForSingleObject(g_hProgressEvent,PROGRESS_SLEEP_TIME));
SendMessage(g_hProgressWnd, PBM_SETPOS ,(WPARAM)PROGRESS_MAX_VAL, 0);
*/
ExitThread(0);
return 0;
}
static DWORD (*g_pfnThread)(void *);
static void * g_vpData;
LRW_DLG_INT CALLBACK
ProgressProc(
IN HWND hwnd,
IN UINT uMsg,
IN WPARAM wParam,
IN LPARAM lParam
);
DWORD ShowProgressBox(HWND hwnd,
DWORD (*pfnThread)(void *vpData),
DWORD dwTitle,
DWORD dwProgressText,
void * vpData)
{
DWORD dwReturn = ERROR_SUCCESS;
g_pfnThread = pfnThread;
g_vpData = vpData;
DialogBox( GetGlobalContext()->GetInstanceHandle(),
MAKEINTRESOURCE(IDD_AUTHENTICATE),
hwnd,
ProgressProc);
return dwReturn;
}
LRW_DLG_INT CALLBACK
ProgressProc(
IN HWND hwnd,
IN UINT uMsg,
IN WPARAM wParam,
IN LPARAM lParam
)
{
BOOL bStatus = FALSE;
static int nCounter;
static HWND hProgress;
static HANDLE hThread;
if (uMsg == WM_INITDIALOG)
{
DWORD dwTID = 0;
ShowWindow(hwnd, SW_SHOWNORMAL);
SetTimer(hwnd, 1, 500, NULL);
hProgress = GetDlgItem(hwnd, IDC_PROGRESSBAR);
hThread = CreateThread(NULL, 0, g_pfnThread, g_vpData, 0, &dwTID);
//Set the range & the initial position
SendMessage(hProgress, PBM_SETRANGE, 0, MAKELPARAM(0,PROGRESS_MAX_VAL));
SendMessage(hProgress, PBM_SETPOS ,(WPARAM)0, 0);
// Set Title & the Introductory text
// Create thread to process the request
}
else if (uMsg == WM_CLOSE)
{
KillTimer(hwnd, 1);
}
else if (uMsg == WM_TIMER)
{
if (WAIT_OBJECT_0 != WaitForSingleObject(hThread, 0))
{
nCounter++;
if (nCounter < PROGRESS_MAX_VAL-5)
{
SendMessage(hProgress, PBM_DELTAPOS ,(WPARAM)PROGRESS_STEP_VAL, 0);
}
}
else
{
SendMessage(hProgress, PBM_SETPOS ,(WPARAM)PROGRESS_MAX_VAL, 0);
CloseHandle(hThread);
EndDialog(hwnd, 0);
}
}
return bStatus;
}
void SetInstanceHandle(HINSTANCE hInst)
{
g_CGlobal->SetInstanceHandle(hInst);
}
void SetLSName(LPTSTR lpstrLSName)
{
g_CGlobal->SetLSName(lpstrLSName);
}
HINSTANCE GetInstanceHandle()
{
return g_CGlobal->GetInstanceHandle();
}
DWORD InitGlobal()
{
return g_CGlobal->InitGlobal();
}
DWORD CheckRequieredFields()
{
return g_CGlobal->CheckRequieredFields();
}
//
// This function loads the Message Text from the String Table and displays
// the given message
//
int LRMessageBox(HWND hWndParent,DWORD dwMsgId,DWORD dwErrorCode /*=0*/)
{
return g_CGlobal->LRMessageBox(hWndParent,dwMsgId,dwErrorCode);
}
//
// This function tries to connect to the LS using LSAPI and returns TRUE if
// successful to connect else returns FALSE
//
BOOL IsLSRunning()
{
return g_CGlobal->IsLSRunning();
}
//
// This function gets LS Certs and stores Certs & Cert Extensions in the
// CGlobal object. If no certs , it returns IDS_ERR_NO_CERT
//
//
// This function is used only in ONLINE mode to authenticate LS.
// Assumption - GetLSCertificates should have been called before calling
// this function.
//
DWORD AuthenticateLS()
{
return g_CGlobal->AuthenticateLS();
}
DWORD LRGetLastError()
{
return g_CGlobal->LRGetLastError();
}
TCHAR * GetRegistrationID(void)
{
return g_CGlobal->GetRegistrationID();
}
TCHAR * GetLicenseServerID(void)
{
return g_CGlobal->GetLicenseServerID();
}
void SetRequestType(DWORD dwMode)
{
g_CGlobal->SetRequestType(dwMode);
}
int GetRequestType(void)
{
return g_CGlobal->GetRequestType();
}
BOOL IsOnlineCertRequestCreated()
{
return g_CGlobal->IsOnlineCertRequestCreated();
}
DWORD SetLRState(DWORD dwState)
{
return g_CGlobal->SetLRState(dwState);
}
DWORD SetCertificatePIN(LPTSTR lpszPIN)
{
return g_CGlobal->SetCertificatePIN(lpszPIN);
}
DWORD PopulateCountryComboBox(HWND hWndCmb)
{
return g_CGlobal->PopulateCountryComboBox(hWndCmb);
}
DWORD GetCountryCode(CString sDesc,LPTSTR szCode)
{
return g_CGlobal->GetCountryCode(sDesc,szCode);
}
DWORD PopulateProductComboBox(HWND hWndCmb)
{
return g_CGlobal->PopulateProductComboBox(hWndCmb);
}
DWORD GetProductCode(CString sDesc,LPTSTR szCode)
{
return g_CGlobal->GetProductCode(sDesc,szCode);
}
DWORD PopulateReasonComboBox(HWND hWndCmb, DWORD dwType)
{
return g_CGlobal->PopulateReasonComboBox(hWndCmb, dwType);
}
DWORD GetReasonCode(CString sDesc,LPTSTR szCode, DWORD dwType)
{
return g_CGlobal->GetReasonCode(sDesc,szCode, dwType);
}
DWORD ProcessRequest()
{
return g_CGlobal->ProcessRequest();
}
void LRSetLastRetCode(DWORD dwCode)
{
g_CGlobal->LRSetLastRetCode(dwCode);
}
DWORD LRGetLastRetCode()
{
return g_CGlobal->LRGetLastRetCode();
}
void LRPush(DWORD dwPageId)
{
g_CGlobal->LRPush(dwPageId);
}
DWORD LRPop()
{
return g_CGlobal->LRPop();
}
BOOL ValidateEmailId(CString sEmailId)
{
return g_CGlobal->ValidateEmailId(sEmailId);
}
BOOL CheckProgramValidity(CString sProgramName)
{
return g_CGlobal->CheckProgramValidity(sProgramName);
}
BOOL ValidateLRString(CString sStr)
{
return g_CGlobal->ValidateLRString(sStr);
}
DWORD PopulateCountryRegionComboBox(HWND hWndCmb)
{
return g_CGlobal->PopulateCountryRegionComboBox(hWndCmb);
}
DWORD SetLSLKP(TCHAR * tcLKP)
{
return g_CGlobal->SetLSLKP(tcLKP);
}
DWORD PingCH(void)
{
return g_CGlobal->PingCH();
}
DWORD AddRetailSPKToList(HWND hListView, TCHAR * lpszRetailSPK)
{
return g_CGlobal->AddRetailSPKToList(hListView, lpszRetailSPK);
}
void DeleteRetailSPKFromList(TCHAR * lpszRetailSPK)
{
g_CGlobal->DeleteRetailSPKFromList(lpszRetailSPK);
return;
}
void LoadFromList(HWND hListView)
{
g_CGlobal->LoadFromList(hListView);
return;
}
void UpdateSPKStatus(TCHAR * lpszRetailSPK, TCHAR tcStatus)
{
g_CGlobal->UpdateSPKStatus(lpszRetailSPK, tcStatus);
return;
}
DWORD SetConfirmationNumber(TCHAR * tcConf)
{
return g_CGlobal->SetConfirmationNumber(tcConf);
}
DWORD SetLSSPK(TCHAR * tcp)
{
return g_CGlobal->SetLSSPK(tcp);
}
void SetCSRNumber(TCHAR * tcp)
{
g_CGlobal->SetCSRNumber(tcp);
return;
}
TCHAR * GetCSRNumber(void)
{
return g_CGlobal->GetCSRNumber();
}
void SetWWWSite(TCHAR * tcp)
{
g_CGlobal->SetWWWSite(tcp);
return;
}
TCHAR * GetWWWSite(void)
{
return g_CGlobal->GetWWWSite();
}
DWORD ResetLSSPK(void)
{
return g_CGlobal->ResetLSSPK();
}
void SetReFresh(DWORD dw)
{
g_CGlobal->SetReFresh(dw);
}
DWORD GetReFresh(void)
{
return g_CGlobal->GetReFresh();
}
void SetModifiedRetailSPK(CString sRetailSPK)
{
g_CGlobal->SetModifiedRetailSPK(sRetailSPK);
}
void GetModifiedRetailSPK(CString &sRetailSPK)
{
g_CGlobal->GetModifiedRetailSPK(sRetailSPK);
}
void ModifyRetailSPKFromList(TCHAR * lpszOldSPK,TCHAR * lpszNewSPK)
{
g_CGlobal->ModifyRetailSPKFromList(lpszOldSPK,lpszNewSPK);
}
DWORD ValidateRetailSPK(TCHAR * lpszRetailSPK)
{
return g_CGlobal->ValidateRetailSPK(lpszRetailSPK);
}
DWORD GetCountryDesc(CString sCode,LPTSTR szDesc)
{
return g_CGlobal->GetCountryDesc(sCode, szDesc);
}
DWORD CGlobal::SetEncodedInRegistry(LPCSTR lpszOID, LPCTSTR lpszValue)
{
HKEY hKey = NULL;
DWORD dwDisposition = 0;
DWORD dwRetCode = ERROR_SUCCESS;
DWORD dwLen = 0;
char * cpOut;
HCRYPTPROV hProv = NULL;
HCRYPTKEY hCKey = NULL;
HCRYPTHASH hHash = NULL;
PBYTE pbKey = NULL;
DWORD cbKey = 0;
if(!CryptAcquireContext(&hProv,
NULL,
NULL,
PROV_RSA_FULL,
CRYPT_VERIFYCONTEXT))
{
dwRetCode = GetLastError();
goto done;
}
if(!CryptCreateHash(hProv,
CALG_MD5,
0,
0,
&hHash))
{
dwRetCode = GetLastError();
goto done;
}
if(!CryptHashData(hHash,
(BYTE *) lpszValue,
lstrlen(lpszValue)*sizeof(TCHAR),
0))
{
dwRetCode = GetLastError();
goto done;
}
if(!CryptDeriveKey(hProv,
CALG_RC4,
hHash,
CRYPT_EXPORTABLE,
&hCKey))
{
dwRetCode = GetLastError();
goto done;
}
if(!CryptExportKey(
hCKey,
NULL,
PUBLICKEYBLOB,
0,
NULL,
&cbKey))
{
dwRetCode = GetLastError();
if(dwRetCode != ERROR_SUCCESS && dwRetCode != ERROR_MORE_DATA)
goto done;
pbKey = (PBYTE)HeapAlloc(GetProcessHeap(),HEAP_ZERO_MEMORY,cbKey);
if(!CryptExportKey(
hCKey,
NULL,
PUBLICKEYBLOB,
0,
pbKey,
&cbKey))
{
dwRetCode = GetLastError();
goto done;
}
}
dwRetCode = ConnectToLSRegistry();
if(dwRetCode != ERROR_SUCCESS)
{
goto done;
}
dwRetCode = RegCreateKeyEx ( m_hLSRegKey,
REG_LRWIZ_PARAMS,
0,
NULL,
REG_OPTION_NON_VOLATILE,
KEY_ALL_ACCESS,
NULL,
&hKey,
&dwDisposition);
if(dwRetCode != ERROR_SUCCESS)
{
LRSetLastError(dwRetCode);
dwRetCode = IDS_ERR_REGCREATE_FAILED;
goto done;
}
if (_tcslen(lpszValue) != 0)
{
LSBase64EncodeA ((PBYTE) lpszValue, _tcslen(lpszValue)*sizeof(TCHAR), NULL, &dwLen);
cpOut = new char[dwLen+1];
if (cpOut == NULL)
{
dwRetCode = IDS_ERR_OUTOFMEM;
goto done;
}
memset(cpOut, 0, dwLen+1);
LSBase64EncodeA ((PBYTE) lpszValue, _tcslen(lpszValue)*sizeof(TCHAR), cpOut, &dwLen);
}
else
{
cpOut = new char[2];
memset(cpOut, 0, 2);
}
RegSetValueExA ( hKey,
lpszOID,
0,
REG_SZ,
(PBYTE) cpOut,
dwLen
);
delete cpOut;
done:
if (hKey != NULL)
{
RegCloseKey(hKey);
}
DisconnectLSRegistry();
return dwRetCode;
}