/* $Id: process-win.cpp $ */ /** @file * IPRT - Process, Windows. */ /* * Copyright (C) 2006-2023 Oracle and/or its affiliates. * * This file is part of VirtualBox base platform packages, as * available from https://www.virtualbox.org. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation, in version 3 of the * License. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL), a copy of it is provided in the "COPYING.CDDL" file included * in the VirtualBox distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. * * SPDX-License-Identifier: GPL-3.0-only OR CDDL-1.0 */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define LOG_GROUP RTLOGGROUP_PROCESS #include /* hack */ #include #include #include #ifndef IPRT_NO_CRT # include # include # include #endif #include #include #define _NTDEF_ /* Prevents redefining (P)UNICODE_STRING. */ #include #include #include "internal-r3-win.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /* kernel32.dll: */ //typedef DWORD (WINAPI *PFNWTSGETACTIVECONSOLESESSIONID)(VOID); typedef HANDLE (WINAPI *PFNCREATETOOLHELP32SNAPSHOT)(DWORD, DWORD); typedef BOOL (WINAPI *PFNPROCESS32FIRSTW)(HANDLE, LPPROCESSENTRY32W); typedef BOOL (WINAPI *PFNPROCESS32NEXTW)(HANDLE, LPPROCESSENTRY32W); /* psapi.dll: */ typedef BOOL (WINAPI *PFNENUMPROCESSES)(LPDWORD, DWORD, LPDWORD); typedef DWORD (WINAPI *PFNGETMODULEBASENAMEW)(HANDLE, HMODULE, LPWSTR, DWORD); /* advapi32.dll: */ typedef BOOL (WINAPI *PFNCREATEPROCESSWITHLOGON)(LPCWSTR, LPCWSTR, LPCWSTR, DWORD, LPCWSTR, LPWSTR, DWORD, LPVOID, LPCWSTR, LPSTARTUPINFOW, LPPROCESS_INFORMATION); typedef NTSTATUS (NTAPI *PFNLSALOOKUPNAMES2)(LSA_HANDLE, ULONG, ULONG, PLSA_UNICODE_STRING, PLSA_REFERENCED_DOMAIN_LIST*, PLSA_TRANSLATED_SID2*); /* userenv.dll: */ typedef BOOL (WINAPI *PFNCREATEENVIRONMENTBLOCK)(LPVOID *, HANDLE, BOOL); typedef BOOL (WINAPI *PFNPFNDESTROYENVIRONMENTBLOCK)(LPVOID); typedef BOOL (WINAPI *PFNLOADUSERPROFILEW)(HANDLE, LPPROFILEINFOW); typedef BOOL (WINAPI *PFNUNLOADUSERPROFILE)(HANDLE, HANDLE); /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** Init once structure. */ static RTONCE g_rtProcWinInitOnce = RTONCE_INITIALIZER; /** Critical section protecting the process array. */ static RTCRITSECT g_CritSect; /** The number of processes in the array. */ static uint32_t g_cProcesses; /** The current allocation size. */ static uint32_t g_cProcessesAlloc; /** Array containing the live or non-reaped child processes. */ static struct RTPROCWINENTRY { /** The process ID. */ ULONG_PTR pid; /** The process handle. */ HANDLE hProcess; } *g_paProcesses; /** Structure for storing a user's account info. * Must be free'd with rtProcWinFreeAccountInfo(). */ typedef struct RTPROCWINACCOUNTINFO { /** User name. */ PRTUTF16 pwszUserName; /** Domain this account is tied to. Can be NULL if no domain is being used. */ PRTUTF16 pwszDomain; } RTPROCWINACCOUNTINFO, *PRTPROCWINACCOUNTINFO; /** @name userenv.dll imports (we don't unload it). * They're all optional. So in addition to using g_rtProcWinResolveOnce, the * caller must also check if any of the necessary APIs are NULL pointers. * @{ */ /** Init once structure for run-as-user functions we need. */ static RTONCE g_rtProcWinResolveOnce = RTONCE_INITIALIZER; /* kernel32.dll: */ static PFNCREATETOOLHELP32SNAPSHOT g_pfnCreateToolhelp32Snapshot = NULL; static PFNPROCESS32FIRSTW g_pfnProcess32FirstW = NULL; static PFNPROCESS32NEXTW g_pfnProcess32NextW = NULL; /* psapi.dll: */ static PFNGETMODULEBASENAMEW g_pfnGetModuleBaseNameW = NULL; static PFNENUMPROCESSES g_pfnEnumProcesses = NULL; /* advapi32.dll: */ static PFNCREATEPROCESSWITHLOGON g_pfnCreateProcessWithLogonW = NULL; static decltype(LogonUserW) *g_pfnLogonUserW = NULL; static decltype(CreateProcessAsUserW) *g_pfnCreateProcessAsUserW = NULL; /* user32.dll: */ static decltype(OpenWindowStationW) *g_pfnOpenWindowStationW = NULL; static decltype(CloseWindowStation) *g_pfnCloseWindowStation = NULL; /* userenv.dll: */ static PFNCREATEENVIRONMENTBLOCK g_pfnCreateEnvironmentBlock = NULL; static PFNPFNDESTROYENVIRONMENTBLOCK g_pfnDestroyEnvironmentBlock = NULL; static PFNLOADUSERPROFILEW g_pfnLoadUserProfileW = NULL; static PFNUNLOADUSERPROFILE g_pfnUnloadUserProfile = NULL; /** @} */ /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ static int rtProcWinFindExe(uint32_t fFlags, RTENV hEnv, const char *pszExec, PRTUTF16 *ppwszExec); static int rtProcWinCreateEnvBlockAndFindExe(uint32_t fFlags, RTENV hEnv, const char *pszExec, PRTUTF16 *ppwszzBlock, PRTUTF16 *ppwszExec); /** * Clean up the globals. * * @param enmReason Ignored. * @param iStatus Ignored. * @param pvUser Ignored. */ static DECLCALLBACK(void) rtProcWinTerm(RTTERMREASON enmReason, int32_t iStatus, void *pvUser) { NOREF(pvUser); NOREF(iStatus); NOREF(enmReason); RTCritSectDelete(&g_CritSect); size_t i = g_cProcesses; while (i-- > 0) { CloseHandle(g_paProcesses[i].hProcess); g_paProcesses[i].hProcess = NULL; } RTMemFree(g_paProcesses); g_paProcesses = NULL; g_cProcesses = 0; g_cProcessesAlloc = 0; } /** * Initialize the globals. * * @returns IPRT status code. * @param pvUser Ignored. */ static DECLCALLBACK(int32_t) rtProcWinInitOnce(void *pvUser) { NOREF(pvUser); g_cProcesses = 0; g_cProcessesAlloc = 0; g_paProcesses = NULL; int rc = RTCritSectInit(&g_CritSect); if (RT_SUCCESS(rc)) { /** @todo init once, terminate once - this is a generic thing which should * have some kind of static and simpler setup! */ rc = RTTermRegisterCallback(rtProcWinTerm, NULL); if (RT_SUCCESS(rc)) return rc; RTCritSectDelete(&g_CritSect); } return rc; } /** * Gets the process handle for a process from g_paProcesses. * * @returns Process handle if found, NULL if not. * @param pid The process to remove (pid). */ static HANDLE rtProcWinFindPid(RTPROCESS pid) { HANDLE hProcess = NULL; RTCritSectEnter(&g_CritSect); uint32_t i = g_cProcesses; while (i-- > 0) if (g_paProcesses[i].pid == pid) { hProcess = g_paProcesses[i].hProcess; break; } RTCritSectLeave(&g_CritSect); return hProcess; } /** * Removes a process from g_paProcesses and closes the process handle. * * @param pid The process to remove (pid). */ static void rtProcWinRemovePid(RTPROCESS pid) { RTCritSectEnter(&g_CritSect); uint32_t i = g_cProcesses; while (i-- > 0) if (g_paProcesses[i].pid == pid) { HANDLE hProcess = g_paProcesses[i].hProcess; g_cProcesses--; uint32_t cToMove = g_cProcesses - i; if (cToMove) memmove(&g_paProcesses[i], &g_paProcesses[i + 1], cToMove * sizeof(g_paProcesses[0])); RTCritSectLeave(&g_CritSect); CloseHandle(hProcess); return; } RTCritSectLeave(&g_CritSect); } /** * Adds a process to g_paProcesses. * * @returns IPRT status code. * @param pid The process id. * @param hProcess The process handle. */ static int rtProcWinAddPid(RTPROCESS pid, HANDLE hProcess) { RTCritSectEnter(&g_CritSect); uint32_t i = g_cProcesses; if (i >= g_cProcessesAlloc) { void *pvNew = RTMemRealloc(g_paProcesses, (i + 16) * sizeof(g_paProcesses[0])); if (RT_UNLIKELY(!pvNew)) { RTCritSectLeave(&g_CritSect); return VERR_NO_MEMORY; } g_paProcesses = (struct RTPROCWINENTRY *)pvNew; g_cProcessesAlloc = i + 16; } g_paProcesses[i].pid = pid; g_paProcesses[i].hProcess = hProcess; g_cProcesses = i + 1; RTCritSectLeave(&g_CritSect); return VINF_SUCCESS; } /** * Initialize the import APIs for run-as-user and special environment support. * * @returns IPRT status code. * @param pvUser Ignored. */ static DECLCALLBACK(int) rtProcWinResolveOnce(void *pvUser) { int rc; RTLDRMOD hMod; RT_NOREF_PV(pvUser); /* * kernel32.dll APIs introduced after NT4. */ g_pfnCreateToolhelp32Snapshot = (PFNCREATETOOLHELP32SNAPSHOT)GetProcAddress(g_hModKernel32, "CreateToolhelp32Snapshot"); g_pfnProcess32FirstW = (PFNPROCESS32FIRSTW )GetProcAddress(g_hModKernel32, "Process32FirstW"); g_pfnProcess32NextW = (PFNPROCESS32NEXTW )GetProcAddress(g_hModKernel32, "Process32NextW"); /* * psapi.dll APIs, if none of the above are available. */ if ( !g_pfnCreateToolhelp32Snapshot || !g_pfnProcess32FirstW || !g_pfnProcess32NextW) { Assert(!g_pfnCreateToolhelp32Snapshot && !g_pfnProcess32FirstW && !g_pfnProcess32NextW); rc = RTLdrLoadSystem("psapi.dll", true /*fNoUnload*/, &hMod); if (RT_SUCCESS(rc)) { rc = RTLdrGetSymbol(hMod, "GetModuleBaseNameW", (void **)&g_pfnGetModuleBaseNameW); AssertStmt(RT_SUCCESS(rc), g_pfnGetModuleBaseNameW = NULL); rc = RTLdrGetSymbol(hMod, "EnumProcesses", (void **)&g_pfnEnumProcesses); AssertStmt(RT_SUCCESS(rc), g_pfnEnumProcesses = NULL); RTLdrClose(hMod); } } /* * advapi32.dll APIs. */ rc = RTLdrLoadSystem("advapi32.dll", true /*fNoUnload*/, &hMod); if (RT_SUCCESS(rc)) { rc = RTLdrGetSymbol(hMod, "CreateProcessWithLogonW", (void **)&g_pfnCreateProcessWithLogonW); if (RT_FAILURE(rc)) { g_pfnCreateProcessWithLogonW = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT4); } rc = RTLdrGetSymbol(hMod, "LogonUserW", (void **)&g_pfnLogonUserW); if (RT_FAILURE(rc)) { g_pfnLogonUserW = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT350); } rc = RTLdrGetSymbol(hMod, "CreateProcessAsUserW", (void **)&g_pfnCreateProcessAsUserW); if (RT_FAILURE(rc)) { g_pfnCreateProcessAsUserW = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT350); } RTLdrClose(hMod); } /* * user32.dll APIs. */ rc = RTLdrLoadSystem("user32.dll", true /*fNoUnload*/, &hMod); if (RT_SUCCESS(rc)) { rc = RTLdrGetSymbol(hMod, "OpenWindowStationW", (void **)&g_pfnOpenWindowStationW); if (RT_FAILURE(rc)) { g_pfnOpenWindowStationW = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT310); } rc = RTLdrGetSymbol(hMod, "CloseWindowStation", (void **)&g_pfnCloseWindowStation); if (RT_FAILURE(rc)) { g_pfnCloseWindowStation = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT310); } RTLdrClose(hMod); } /* * userenv.dll APIs. */ rc = RTLdrLoadSystem("userenv.dll", true /*fNoUnload*/, &hMod); if (RT_SUCCESS(rc)) { rc = RTLdrGetSymbol(hMod, "LoadUserProfileW", (void **)&g_pfnLoadUserProfileW); if (RT_FAILURE(rc)) { g_pfnLoadUserProfileW = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT4); } rc = RTLdrGetSymbol(hMod, "UnloadUserProfile", (void **)&g_pfnUnloadUserProfile); if (RT_FAILURE(rc)) { g_pfnUnloadUserProfile = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT4); } rc = RTLdrGetSymbol(hMod, "CreateEnvironmentBlock", (void **)&g_pfnCreateEnvironmentBlock); if (RT_FAILURE(rc)) { g_pfnCreateEnvironmentBlock = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT4); } rc = RTLdrGetSymbol(hMod, "DestroyEnvironmentBlock", (void **)&g_pfnDestroyEnvironmentBlock); if (RT_FAILURE(rc)) { g_pfnDestroyEnvironmentBlock = NULL; Assert(g_enmWinVer <= kRTWinOSType_NT4); } RTLdrClose(hMod); } return VINF_SUCCESS; } RTR3DECL(int) RTProcCreate(const char *pszExec, const char * const *papszArgs, RTENV Env, unsigned fFlags, PRTPROCESS pProcess) { return RTProcCreateEx(pszExec, papszArgs, Env, fFlags, NULL, NULL, NULL, /* standard handles */ NULL /*pszAsUser*/, NULL /* pszPassword*/, NULL /*pvExtraData*/, pProcess); } /** * The following NT call is for v3.51 and does the equivalent of: * DuplicateTokenEx(hSrcToken, MAXIMUM_ALLOWED, NULL, * SecurityIdentification, TokenPrimary, phToken); */ static int rtProcWinDuplicateToken(HANDLE hSrcToken, PHANDLE phToken) { int rc; if (g_pfnNtDuplicateToken) { SECURITY_QUALITY_OF_SERVICE SecQoS; SecQoS.Length = sizeof(SecQoS); SecQoS.ImpersonationLevel = SecurityIdentification; SecQoS.ContextTrackingMode = SECURITY_DYNAMIC_TRACKING; SecQoS.EffectiveOnly = FALSE; OBJECT_ATTRIBUTES ObjAttr; InitializeObjectAttributes(&ObjAttr, NULL /*Name*/, 0 /*OBJ_XXX*/, NULL /*Root*/, NULL /*SecDesc*/); ObjAttr.SecurityQualityOfService = &SecQoS; NTSTATUS rcNt = g_pfnNtDuplicateToken(hSrcToken, MAXIMUM_ALLOWED, &ObjAttr, FALSE, TokenPrimary, phToken); if (NT_SUCCESS(rcNt)) rc = VINF_SUCCESS; else rc = RTErrConvertFromNtStatus(rcNt); } else rc = VERR_SYMBOL_NOT_FOUND; /** @todo do we really need to duplicate the token? */ return rc; } /** * Get the token assigned to the thread indicated by @a hThread. * * Only used when RTPROC_FLAGS_AS_IMPERSONATED_TOKEN is in effect and the * purpose is to get a duplicate the impersonated token of the current thread. * * @returns IPRT status code. * @param hThread The thread handle (current thread). * @param phToken Where to return the a duplicate of the thread token * handle on success. (The caller closes it.) */ static int rtProcWinGetThreadTokenHandle(HANDLE hThread, PHANDLE phToken) { AssertPtr(phToken); int rc; HANDLE hTokenThread; if (OpenThreadToken(hThread, TOKEN_ADJUST_PRIVILEGES | TOKEN_QUERY | TOKEN_DUPLICATE | TOKEN_ASSIGN_PRIMARY | TOKEN_ADJUST_SESSIONID | TOKEN_READ | TOKEN_WRITE, TRUE /* OpenAsSelf - for impersonation at SecurityIdentification level */, &hTokenThread)) { rc = rtProcWinDuplicateToken(hTokenThread, phToken); CloseHandle(hTokenThread); } else rc = RTErrConvertFromWin32(GetLastError()); return rc; } /** * Get the token assigned the process indicated by @a hProcess. * * Only used when pwszUser is NULL and RTPROC_FLAGS_AS_IMPERSONATED_TOKEN isn't * set. * * @returns IPRT status code. * @param hProcess The process handle (current process). * @param phToken Where to return the a duplicate of the thread token * handle on success. (The caller closes it.) */ static int rtProcWinGetProcessTokenHandle(HANDLE hProcess, PHANDLE phToken) { AssertPtr(phToken); int rc; HANDLE hTokenProcess; if (OpenProcessToken(hProcess, TOKEN_ADJUST_PRIVILEGES | TOKEN_QUERY | TOKEN_DUPLICATE | TOKEN_ASSIGN_PRIMARY | TOKEN_ADJUST_SESSIONID | TOKEN_READ | TOKEN_WRITE, &hTokenProcess)) { rc = rtProcWinDuplicateToken(hTokenProcess, phToken); /* not sure if this is strictly necessary */ CloseHandle(hTokenProcess); } else rc = RTErrConvertFromWin32(GetLastError()); return rc; } /** * Get the process token of the process indicated by @a dwPID if the @a pSid and * @a idSessionDesired matches. * * @returns IPRT status code. * @param dwPid The process identifier. * @param pSid The secure identifier of the user. * @param idDesiredSession The session the process candidate should * preferably belong to, UINT32_MAX if anything * goes. * @param phToken Where to return the a duplicate of the process token * handle on success. (The caller closes it.) */ static int rtProcWinGetProcessTokenHandle(DWORD dwPid, PSID pSid, DWORD idDesiredSession, PHANDLE phToken) { AssertPtr(pSid); AssertPtr(phToken); int rc; HANDLE hProc = OpenProcess(MAXIMUM_ALLOWED, TRUE, dwPid); if (hProc != NULL) { HANDLE hTokenProc; if (OpenProcessToken(hProc, TOKEN_ADJUST_PRIVILEGES | TOKEN_QUERY | TOKEN_DUPLICATE | TOKEN_IMPERSONATE | TOKEN_ASSIGN_PRIMARY | TOKEN_ADJUST_SESSIONID | TOKEN_READ | TOKEN_WRITE, &hTokenProc)) { /* * Query the user SID from the token. */ SetLastError(NO_ERROR); DWORD dwSize = 0; BOOL fRc = GetTokenInformation(hTokenProc, TokenUser, NULL, 0, &dwSize); DWORD dwErr = GetLastError(); if ( !fRc && dwErr == ERROR_INSUFFICIENT_BUFFER && dwSize > 0) { PTOKEN_USER pTokenUser = (PTOKEN_USER)RTMemTmpAllocZ(dwSize); if (pTokenUser) { if (GetTokenInformation(hTokenProc, TokenUser, pTokenUser, dwSize, &dwSize)) { /* * Match token user with the user we're want to create a process as. */ if ( IsValidSid(pTokenUser->User.Sid) && EqualSid(pTokenUser->User.Sid, pSid)) { /* * Do we need to match the session ID? */ rc = VINF_SUCCESS; if (idDesiredSession != UINT32_MAX) { DWORD idCurSession = UINT32_MAX; if (GetTokenInformation(hTokenProc, TokenSessionId, &idCurSession, sizeof(DWORD), &dwSize)) rc = idDesiredSession == idCurSession ? VINF_SUCCESS : VERR_NOT_FOUND; else rc = RTErrConvertFromWin32(GetLastError()); } if (RT_SUCCESS(rc)) { /* * Got a match. Duplicate the token. This duplicated token will * be used for the actual CreateProcessAsUserW() call then. */ rc = rtProcWinDuplicateToken(hTokenProc, phToken); } } else rc = VERR_NOT_FOUND; } else rc = RTErrConvertFromWin32(GetLastError()); RTMemTmpFree(pTokenUser); } else rc = VERR_NO_MEMORY; } else if (fRc || dwErr == NO_ERROR) rc = VERR_IPE_UNEXPECTED_STATUS; else rc = RTErrConvertFromWin32(dwErr); CloseHandle(hTokenProc); } else rc = RTErrConvertFromWin32(GetLastError()); CloseHandle(hProc); } else rc = RTErrConvertFromWin32(GetLastError()); return rc; } /** * Fallback method for rtProcWinFindTokenByProcess that uses the older NT4 * PSAPI.DLL API. * * @returns Success indicator. * @param papszNames The process candidates, in prioritized order. * @param pSid The secure identifier of the user. * @param phToken Where to return the token handle - duplicate, * caller closes it on success. * * @remarks NT4 needs a copy of "PSAPI.dll" (redistributed by Microsoft and not * part of the OS) in order to get a lookup. If we don't have this DLL * we are not able to get a token and therefore no UI will be visible. */ static bool rtProcWinFindTokenByProcessAndPsApi(const char * const *papszNames, PSID pSid, PHANDLE phToken) { /* * Load PSAPI.DLL and resolve the two symbols we need. */ if ( !g_pfnGetModuleBaseNameW || !g_pfnEnumProcesses) return false; /* * Get a list of PID. We retry if it looks like there are more PIDs * to be returned than what we supplied buffer space for. */ bool fFound = false; int rc = VINF_SUCCESS; DWORD cbPidsAllocated = 4096; DWORD cbPidsReturned = 0; /* (MSC maybe used uninitialized) */ DWORD *paPids; for (;;) { paPids = (DWORD *)RTMemTmpAlloc(cbPidsAllocated); AssertBreakStmt(paPids, rc = VERR_NO_TMP_MEMORY); cbPidsReturned = 0; if (!g_pfnEnumProcesses(paPids, cbPidsAllocated, &cbPidsReturned)) { rc = RTErrConvertFromWin32(GetLastError()); AssertMsgFailedBreak(("%Rrc\n", rc)); } if ( cbPidsReturned < cbPidsAllocated || cbPidsAllocated >= _512K) break; RTMemTmpFree(paPids); cbPidsAllocated *= 2; } if (RT_SUCCESS(rc)) { /* * Search for the process. * * We ASSUME that the caller won't be specifying any names longer * than RTPATH_MAX. */ PRTUTF16 pwszProcName = (PRTUTF16)RTMemTmpAllocZ(RTPATH_MAX * sizeof(pwszProcName[0])); if (pwszProcName) { for (size_t i = 0; papszNames[i] && !fFound; i++) { const DWORD cPids = cbPidsReturned / sizeof(DWORD); for (DWORD iPid = 0; iPid < cPids && !fFound; iPid++) { HANDLE hProc = OpenProcess(PROCESS_QUERY_INFORMATION | PROCESS_VM_READ, FALSE, paPids[iPid]); if (hProc) { *pwszProcName = '\0'; DWORD cbRet = g_pfnGetModuleBaseNameW(hProc, 0 /*hModule = exe */, pwszProcName, RTPATH_MAX); if ( cbRet > 0 && RTUtf16ICmpAscii(pwszProcName, papszNames[i]) == 0 && RT_SUCCESS(rtProcWinGetProcessTokenHandle(paPids[iPid], pSid, UINT32_MAX, phToken))) fFound = true; CloseHandle(hProc); } } } RTMemTmpFree(pwszProcName); } else rc = VERR_NO_TMP_MEMORY; } RTMemTmpFree(paPids); return fFound; } /** * Finds a one of the processes in @a papszNames running with user @a pSid and possibly * in the required windows session. Returns a duplicate handle to its token. * * @returns Success indicator. * @param papszNames The process candidates, in prioritized order. * @param pSid The secure identifier of the user. * @param idDesiredSession The session the process candidate should * belong to if possible, UINT32_MAX if anything * goes. * @param phToken Where to return the token handle - duplicate, * caller closes it on success. */ static bool rtProcWinFindTokenByProcess(const char * const *papszNames, PSID pSid, uint32_t idDesiredSession, PHANDLE phToken) { AssertPtr(papszNames); AssertPtr(pSid); AssertPtr(phToken); bool fFound = false; /* * On modern systems (W2K+) try the Toolhelp32 API first; this is more stable * and reliable. Fallback to EnumProcess on NT4. */ bool fFallback = true; if (g_pfnProcess32NextW && g_pfnProcess32FirstW && g_pfnCreateToolhelp32Snapshot) { HANDLE hSnap = g_pfnCreateToolhelp32Snapshot(TH32CS_SNAPPROCESS, 0); Assert(hSnap != INVALID_HANDLE_VALUE); if (hSnap != INVALID_HANDLE_VALUE) { fFallback = false; for (size_t i = 0; papszNames[i] && !fFound; i++) { PROCESSENTRY32W ProcEntry; ProcEntry.dwSize = sizeof(ProcEntry); ProcEntry.szExeFile[0] = '\0'; if (g_pfnProcess32FirstW(hSnap, &ProcEntry)) { do { if (RTUtf16ICmpAscii(ProcEntry.szExeFile, papszNames[i]) == 0) { int rc = rtProcWinGetProcessTokenHandle(ProcEntry.th32ProcessID, pSid, idDesiredSession, phToken); if (RT_SUCCESS(rc)) { fFound = true; break; } } } while (g_pfnProcess32NextW(hSnap, &ProcEntry)); } else AssertMsgFailed(("dwErr=%u (%x)\n", GetLastError(), GetLastError())); } CloseHandle(hSnap); } } /* If we couldn't take a process snapshot for some reason or another, fall back on the NT4 compatible API. */ if (fFallback) fFound = rtProcWinFindTokenByProcessAndPsApi(papszNames, pSid, phToken); return fFound; } /** * Logs on a specified user and returns its primary token. * * @returns IPRT status code. * @param pwszUser User name. A domain name can be specified (as part of a UPN, User Principal Name), * e.g. "joedoe@example.com". * @param pwszPassword Password. * @param phToken Pointer to store the logon token. */ static int rtProcWinUserLogon(PRTUTF16 pwszUser, PRTUTF16 pwszPassword, HANDLE *phToken) { AssertPtrReturn(pwszUser, VERR_INVALID_POINTER); AssertPtrReturn(pwszPassword, VERR_INVALID_POINTER); AssertPtrReturn(phToken, VERR_INVALID_POINTER); if (!g_pfnLogonUserW) return VERR_NOT_SUPPORTED; /* * Because we have to deal with http://support.microsoft.com/kb/245683 * for NULL domain names when running on NT4 here, pass an empty string if so. * However, passing FQDNs should work! * * The SE_TCB_NAME (Policy: Act as part of the operating system) right * is required on older windows versions (NT4, W2K, possibly XP). */ PCRTUTF16 pwszDomainNone = g_enmWinVer < kRTWinOSType_2K ? L"" /* NT4 and older */ : NULL /* Windows 2000 and up */; BOOL fRc = g_pfnLogonUserW(pwszUser, /* The domain always is passed as part of the UPN (user name). */ pwszDomainNone, pwszPassword, LOGON32_LOGON_INTERACTIVE, LOGON32_PROVIDER_DEFAULT, phToken); if (fRc) return VINF_SUCCESS; DWORD dwErr = GetLastError(); int rc = dwErr == ERROR_PRIVILEGE_NOT_HELD ? VERR_PROC_TCB_PRIV_NOT_HELD : RTErrConvertFromWin32(dwErr); if (rc == VERR_UNRESOLVED_ERROR) LogRelFunc(("dwErr=%u (%#x), rc=%Rrc\n", dwErr, dwErr, rc)); return rc; } /** * Returns the environment to use for the child process. * * This implements the RTPROC_FLAGS_ENV_CHANGE_RECORD and environment related * parts of RTPROC_FLAGS_PROFILE. * * @returns IPRT status code. * @param hToken The user token to use if RTPROC_FLAGS_PROFILE is given. * The caller must have loaded profile for this. * @param hEnv The environment passed in by the RTProcCreateEx caller. * @param fFlags The process creation flags passed in by the * RTProcCreateEx caller (RTPROC_FLAGS_XXX). * @param phEnv Where to return the environment to use. This can either * be a newly created environment block or @a hEnv. In the * former case, the caller must destroy it. */ static int rtProcWinCreateEnvFromToken(HANDLE hToken, RTENV hEnv, uint32_t fFlags, PRTENV phEnv) { int rc; /* * Query the environment from the user profile associated with the token if * the caller has specified it directly or indirectly. */ if ( (fFlags & RTPROC_FLAGS_PROFILE) && ( hEnv == RTENV_DEFAULT || (fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD)) ) { if (g_pfnCreateEnvironmentBlock && g_pfnDestroyEnvironmentBlock) { LPVOID pvEnvBlockProfile = NULL; if (g_pfnCreateEnvironmentBlock(&pvEnvBlockProfile, hToken, FALSE /* Don't inherit from parent. */)) { rc = RTEnvCloneUtf16Block(phEnv, (PCRTUTF16)pvEnvBlockProfile, 0 /*fFlags*/); if ( (fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD) && RT_SUCCESS(rc) && hEnv != RTENV_DEFAULT) { rc = RTEnvApplyChanges(*phEnv, hEnv); if (RT_FAILURE(rc)) RTEnvDestroy(*phEnv); } g_pfnDestroyEnvironmentBlock(pvEnvBlockProfile); } else rc = RTErrConvertFromWin32(GetLastError()); } else rc = VERR_SYMBOL_NOT_FOUND; } /* * We we've got an incoming change record, combine it with the default environment. */ else if (hEnv != RTENV_DEFAULT && (fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD)) { rc = RTEnvClone(phEnv, RTENV_DEFAULT); if (RT_SUCCESS(rc)) { rc = RTEnvApplyChanges(*phEnv, hEnv); if (RT_FAILURE(rc)) RTEnvDestroy(*phEnv); } } /* * Otherwise we can return the incoming environment directly. */ else { *phEnv = hEnv; rc = VINF_SUCCESS; } return rc; } /** * Figures which privilege we're missing for success application of * CreateProcessAsUserW. * * @returns IPRT error status. */ static int rtProcWinFigureWhichPrivilegeNotHeld2(void) { HANDLE hToken; if (OpenProcessToken(GetCurrentProcess(), TOKEN_QUERY | TOKEN_ADJUST_PRIVILEGES, &hToken)) { static struct { const char *pszName; int rc; } const s_aPrivileges[] = { { SE_TCB_NAME, VERR_PROC_TCB_PRIV_NOT_HELD }, { SE_ASSIGNPRIMARYTOKEN_NAME, VERR_PROC_APT_PRIV_NOT_HELD }, { SE_INCREASE_QUOTA_NAME, VERR_PROC_IQ_PRIV_NOT_HELD }, }; for (uint32_t i = 0; i < RT_ELEMENTS(s_aPrivileges); i++) { union { TOKEN_PRIVILEGES TokPriv; char abAlloced[sizeof(TOKEN_PRIVILEGES) + sizeof(LUID_AND_ATTRIBUTES)]; } uNew, uOld; uNew.TokPriv.PrivilegeCount = 1; uNew.TokPriv.Privileges[0].Attributes = SE_PRIVILEGE_ENABLED; AssertContinue(LookupPrivilegeValue(NULL, s_aPrivileges[i].pszName, &uNew.TokPriv.Privileges[0].Luid)); uOld = uNew; SetLastError(NO_ERROR); DWORD cbActual = RT_UOFFSETOF(TOKEN_PRIVILEGES, Privileges[1]); AdjustTokenPrivileges(hToken, FALSE /*fDisableAllPrivileges*/, &uNew.TokPriv, cbActual, &uOld.TokPriv, &cbActual); if (GetLastError() != NO_ERROR) { CloseHandle(hToken); return s_aPrivileges[i].rc; } if (uOld.TokPriv.Privileges[0].Attributes == 0) AdjustTokenPrivileges(hToken, FALSE /*fDisableAllPrivileges*/, &uOld.TokPriv, 0, NULL, NULL); } AssertFailed(); CloseHandle(hToken); } else AssertFailed(); return VERR_PRIVILEGE_NOT_HELD; } #if 0 /* debug code */ static char *rtProcWinSidToString(char *psz, PSID pSid) { char *pszRet = psz; *psz++ = 'S'; *psz++ = '-'; *psz++ = '1'; *psz++ = '-'; PISID pISid = (PISID)pSid; psz += RTStrFormatU32(psz, 32, RT_MAKE_U32_FROM_U8(pISid->IdentifierAuthority.Value[5], pISid->IdentifierAuthority.Value[4], pISid->IdentifierAuthority.Value[3], pISid->IdentifierAuthority.Value[2]), 10, 0, 0, 0); for (unsigned i = 0; i < pISid->SubAuthorityCount; i++) { *psz++ = '-'; psz += RTStrFormatU32(psz, 32, pISid->SubAuthority[i], 10, 0, 0, 0); } *psz++ = '\0'; return pszRet; } static void rtProcWinLogAcl(PACL pAcl) { if (!pAcl) RTAssertMsg2("ACL is NULL\n"); else { RTAssertMsg2("AceCount=%d AclSize=%#x AclRevision=%d\n", pAcl->AceCount, pAcl->AclSize, pAcl->AclRevision); for (uint32_t i = 0; i < pAcl->AceCount; i++) { PACE_HEADER pAceHdr = NULL; if (GetAce(pAcl, i, (PVOID *)&pAceHdr)) { RTAssertMsg2(" ACE[%u]: Flags=%#x Type=%#x Size=%#x", i, pAceHdr->AceFlags, pAceHdr->AceType, pAceHdr->AceSize); char szTmp[256]; if (pAceHdr->AceType == ACCESS_ALLOWED_ACE_TYPE) RTAssertMsg2(" Mask=%#x %s\n", ((ACCESS_ALLOWED_ACE *)pAceHdr)->Mask, rtProcWinSidToString(szTmp, &((ACCESS_ALLOWED_ACE *)pAceHdr)->SidStart)); else RTAssertMsg2(" ACE[%u]: Flags=%#x Type=%#x Size=%#x\n", i, pAceHdr->AceFlags, pAceHdr->AceType, pAceHdr->AceSize); } } } } static bool rtProcWinLogSecAttr(HANDLE hUserObj) { /* * Get the security descriptor for the user interface object. */ uint32_t cbSecDesc = _64K; PSECURITY_DESCRIPTOR pSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); SECURITY_INFORMATION SecInfo = DACL_SECURITY_INFORMATION; DWORD cbNeeded; AssertReturn(pSecDesc, false); if (!GetUserObjectSecurity(hUserObj, &SecInfo, pSecDesc, cbSecDesc, &cbNeeded)) { RTMemTmpFree(pSecDesc); AssertReturn(GetLastError() == ERROR_INSUFFICIENT_BUFFER, false); cbSecDesc = cbNeeded + 128; pSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); AssertReturn(pSecDesc, false); if (!GetUserObjectSecurity(hUserObj, &SecInfo, pSecDesc, cbSecDesc, &cbNeeded)) { RTMemTmpFree(pSecDesc); AssertFailedReturn(false); } } /* * Get the discretionary access control list (if we have one). */ BOOL fDaclDefaulted; BOOL fDaclPresent; PACL pDacl; if (GetSecurityDescriptorDacl(pSecDesc, &fDaclPresent, &pDacl, &fDaclDefaulted)) rtProcWinLogAcl(pDacl); else RTAssertMsg2("GetSecurityDescriptorDacl failed\n"); RTMemFree(pSecDesc); return true; } #endif /* debug */ /** * Get the user SID from a token. * * @returns Pointer to the SID on success. Free by calling RTMemFree. * @param hToken The token.. * @param prc Optional return code. */ static PSID rtProcWinGetTokenUserSid(HANDLE hToken, int *prc) { int rcIgn; if (!prc) prc = &rcIgn; *prc = VERR_NO_MEMORY; /* * Get the groups associated with the token. We just try a size first then * reallocates if it's insufficient. */ DWORD cbUser = _1K; PTOKEN_USER pUser = (PTOKEN_USER)RTMemTmpAlloc(cbUser); AssertReturn(pUser, NULL); DWORD cbNeeded = 0; if (!GetTokenInformation(hToken, TokenUser, pUser, cbUser, &cbNeeded)) { DWORD dwErr = GetLastError(); RTMemTmpFree(pUser); AssertLogRelMsgReturnStmt(dwErr == ERROR_INSUFFICIENT_BUFFER, ("rtProcWinGetTokenUserSid: GetTokenInformation failed with %u\n", dwErr), *prc = RTErrConvertFromWin32(dwErr), NULL); cbUser = cbNeeded + 128; pUser = (PTOKEN_USER)RTMemTmpAlloc(cbUser); AssertReturn(pUser, NULL); if (!GetTokenInformation(hToken, TokenUser, pUser, cbUser, &cbNeeded)) { dwErr = GetLastError(); *prc = RTErrConvertFromWin32(dwErr); RTMemTmpFree(pUser); AssertLogRelMsgFailedReturn(("rtProcWinGetTokenUserSid: GetTokenInformation failed with %u\n", dwErr), NULL); } } DWORD cbSid = GetLengthSid(pUser->User.Sid); PSID pSidRet = RTMemDup(pUser->User.Sid, cbSid); Assert(pSidRet); RTMemTmpFree(pUser); *prc = VINF_SUCCESS; return pSidRet; } #if 0 /* not used */ /** * Get the login SID from a token. * * @returns Pointer to the SID on success. Free by calling RTMemFree. * @param hToken The token.. */ static PSID rtProcWinGetTokenLogonSid(HANDLE hToken) { /* * Get the groups associated with the token. We just try a size first then * reallocates if it's insufficient. */ DWORD cbGroups = _1K; PTOKEN_GROUPS pGroups = (PTOKEN_GROUPS)RTMemTmpAlloc(cbGroups); AssertReturn(pGroups, NULL); DWORD cbNeeded = 0; if (!GetTokenInformation(hToken, TokenGroups, pGroups, cbGroups, &cbNeeded)) { RTMemTmpFree(pGroups); AssertReturn(GetLastError() == ERROR_INSUFFICIENT_BUFFER, NULL); cbGroups = cbNeeded + 128; pGroups = (PTOKEN_GROUPS)RTMemTmpAlloc(cbGroups); AssertReturn(pGroups, NULL); if (!GetTokenInformation(hToken, TokenGroups, pGroups, cbGroups, &cbNeeded)) { RTMemTmpFree(pGroups); AssertFailedReturn(NULL); } } /* * Locate the logon sid. */ PSID pSidRet = NULL; uint32_t i = pGroups->GroupCount; while (i-- > 0) if ((pGroups->Groups[i].Attributes & SE_GROUP_LOGON_ID) == SE_GROUP_LOGON_ID) { DWORD cbSid = GetLengthSid(pGroups->Groups[i].Sid); pSidRet = RTMemDup(pGroups->Groups[i].Sid, cbSid); break; } RTMemTmpFree(pGroups); Assert(pSidRet); return pSidRet; } #endif /* unused */ /** * Retrieves the DACL security descriptor of the give GUI object. * * @returns Pointer to the security descriptor. * @param hUserObj The GUI object handle. * @param pcbSecDesc Where to return the size of the security descriptor. * @param ppDacl Where to return the DACL pointer. * @param pfDaclPresent Where to return the DACL-present indicator. * @param pDaclSizeInfo Where to return the DACL size information. */ static PSECURITY_DESCRIPTOR rtProcWinGetUserObjDacl(HANDLE hUserObj, uint32_t *pcbSecDesc, PACL *ppDacl, BOOL *pfDaclPresent, ACL_SIZE_INFORMATION *pDaclSizeInfo) { /* * Get the security descriptor for the user interface object. */ uint32_t cbSecDesc = _1K; PSECURITY_DESCRIPTOR pSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); SECURITY_INFORMATION SecInfo = DACL_SECURITY_INFORMATION; DWORD cbNeeded; AssertReturn(pSecDesc, NULL); if (!GetUserObjectSecurity(hUserObj, &SecInfo, pSecDesc, cbSecDesc, &cbNeeded)) { RTMemTmpFree(pSecDesc); AssertReturn(GetLastError() == ERROR_INSUFFICIENT_BUFFER, NULL); cbSecDesc = cbNeeded + 128; pSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); AssertReturn(pSecDesc, NULL); if (!GetUserObjectSecurity(hUserObj, &SecInfo, pSecDesc, cbSecDesc, &cbNeeded)) { RTMemTmpFree(pSecDesc); AssertFailedReturn(NULL); } } *pcbSecDesc = cbNeeded; /* * Get the discretionary access control list (if we have one). */ BOOL fDaclDefaulted; if (GetSecurityDescriptorDacl(pSecDesc, pfDaclPresent, ppDacl, &fDaclDefaulted)) { RT_ZERO(*pDaclSizeInfo); pDaclSizeInfo->AclBytesInUse = sizeof(ACL); if ( !*ppDacl || GetAclInformation(*ppDacl, pDaclSizeInfo, sizeof(*pDaclSizeInfo), AclSizeInformation)) return pSecDesc; AssertFailed(); } else AssertFailed(); RTMemTmpFree(pSecDesc); return NULL; } /** * Copy ACEs from one ACL to another. * * @returns true on success, false on failure. * @param pDst The destination ACL. * @param pSrc The source ACL. * @param cAces The number of ACEs to copy. */ static bool rtProcWinCopyAces(PACL pDst, PACL pSrc, uint32_t cAces) { for (uint32_t i = 0; i < cAces; i++) { PACE_HEADER pAceHdr; AssertReturn(GetAce(pSrc, i, (PVOID *)&pAceHdr), false); AssertReturn(AddAce(pDst, ACL_REVISION, MAXDWORD, pAceHdr, pAceHdr->AceSize), false); } return true; } /** * Adds an access-allowed access control entry to an ACL. * * @returns true on success, false on failure. * @param pDstAcl The ACL. * @param fAceFlags The ACE flags. * @param fMask The ACE access mask. * @param pSid The SID to go with the ACE. * @param cbSid The size of the SID. */ static bool rtProcWinAddAccessAllowedAce(PACL pDstAcl, uint32_t fAceFlags, uint32_t fMask, PSID pSid, uint32_t cbSid) { struct { ACCESS_ALLOWED_ACE Core; DWORD abPadding[128]; /* More than enough, AFAIK. */ } AceBuf; RT_ZERO(AceBuf); uint32_t const cbAllowedAce = RT_UOFFSETOF(ACCESS_ALLOWED_ACE, SidStart) + cbSid; AssertReturn(cbAllowedAce <= sizeof(AceBuf), false); AceBuf.Core.Header.AceSize = cbAllowedAce; AceBuf.Core.Header.AceType = ACCESS_ALLOWED_ACE_TYPE; AceBuf.Core.Header.AceFlags = fAceFlags; AceBuf.Core.Mask = fMask; AssertReturn(CopySid(cbSid, &AceBuf.Core.SidStart, pSid), false); uint32_t i = pDstAcl->AceCount; while (i-- > 0) { PACE_HEADER pAceHdr; AssertContinue(GetAce(pDstAcl, i, (PVOID *)&pAceHdr)); if ( pAceHdr->AceSize == cbAllowedAce && memcmp(pAceHdr, &AceBuf.Core, cbAllowedAce) == 0) return true; } AssertMsgReturn(AddAce(pDstAcl, ACL_REVISION, MAXDWORD, &AceBuf.Core, cbAllowedAce), ("%u\n", GetLastError()), false); return true; } /** All window station rights we know about */ #define MY_WINSTATION_ALL_RIGHTS ( WINSTA_ACCESSCLIPBOARD | WINSTA_ACCESSGLOBALATOMS | WINSTA_CREATEDESKTOP \ | WINSTA_ENUMDESKTOPS | WINSTA_ENUMERATE | WINSTA_EXITWINDOWS | WINSTA_READATTRIBUTES \ | WINSTA_READSCREEN | WINSTA_WRITEATTRIBUTES | DELETE | READ_CONTROL | WRITE_DAC | WRITE_OWNER ) /** All desktop rights we know about */ #define MY_DESKTOP_ALL_RIGHTS ( DESKTOP_CREATEMENU | DESKTOP_CREATEWINDOW | DESKTOP_ENUMERATE | DESKTOP_HOOKCONTROL \ | DESKTOP_JOURNALPLAYBACK | DESKTOP_JOURNALRECORD | DESKTOP_READOBJECTS \ | DESKTOP_SWITCHDESKTOP | DESKTOP_WRITEOBJECTS | DELETE | READ_CONTROL | WRITE_DAC \ | WRITE_OWNER ) /** Generic rights. */ #define MY_GENERIC_ALL_RIGHTS ( GENERIC_READ | GENERIC_WRITE | GENERIC_EXECUTE | GENERIC_ALL ) /** * Grants the given SID full access to the given window station. * * @returns true on success, false on failure. * @param hWinStation The window station. * @param pSid The SID. */ static bool rtProcWinAddSidToWinStation(HWINSTA hWinStation, PSID pSid) { bool fRet = false; /* * Get the current DACL. */ uint32_t cbSecDesc; PACL pDacl; ACL_SIZE_INFORMATION DaclSizeInfo; BOOL fDaclPresent; PSECURITY_DESCRIPTOR pSecDesc = rtProcWinGetUserObjDacl(hWinStation, &cbSecDesc, &pDacl, &fDaclPresent, &DaclSizeInfo); if (pSecDesc) { /* * Create a new DACL. This will contain two extra ACEs. */ PSECURITY_DESCRIPTOR pNewSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); if ( pNewSecDesc && InitializeSecurityDescriptor(pNewSecDesc, SECURITY_DESCRIPTOR_REVISION)) { uint32_t const cbSid = GetLengthSid(pSid); uint32_t const cbNewDacl = DaclSizeInfo.AclBytesInUse + (sizeof(ACCESS_ALLOWED_ACE) + cbSid) * 2; PACL pNewDacl = (PACL)RTMemTmpAlloc(cbNewDacl); if ( pNewDacl && InitializeAcl(pNewDacl, cbNewDacl, ACL_REVISION) && rtProcWinCopyAces(pNewDacl, pDacl, fDaclPresent ? DaclSizeInfo.AceCount : 0)) { /* * Add the two new SID ACEs. */ if ( rtProcWinAddAccessAllowedAce(pNewDacl, CONTAINER_INHERIT_ACE | INHERIT_ONLY_ACE | OBJECT_INHERIT_ACE, MY_GENERIC_ALL_RIGHTS, pSid, cbSid) && rtProcWinAddAccessAllowedAce(pNewDacl, NO_PROPAGATE_INHERIT_ACE, MY_WINSTATION_ALL_RIGHTS, pSid, cbSid)) { /* * Now mate the new DECL with the security descriptor and set it. */ if (SetSecurityDescriptorDacl(pNewSecDesc, TRUE /*fDaclPresent*/, pNewDacl, FALSE /*fDaclDefaulted*/)) { SECURITY_INFORMATION SecInfo = DACL_SECURITY_INFORMATION; if (SetUserObjectSecurity(hWinStation, &SecInfo, pNewSecDesc)) fRet = true; else AssertFailed(); } else AssertFailed(); } else AssertFailed(); } else AssertFailed(); RTMemTmpFree(pNewDacl); } else AssertFailed(); RTMemTmpFree(pNewSecDesc); RTMemTmpFree(pSecDesc); } return fRet; } /** * Grants the given SID full access to the given desktop. * * @returns true on success, false on failure. * @param hDesktop The desktop handle. * @param pSid The SID. */ static bool rtProcWinAddSidToDesktop(HDESK hDesktop, PSID pSid) { bool fRet = false; /* * Get the current DACL. */ uint32_t cbSecDesc; PACL pDacl; ACL_SIZE_INFORMATION DaclSizeInfo; BOOL fDaclPresent; PSECURITY_DESCRIPTOR pSecDesc = rtProcWinGetUserObjDacl(hDesktop, &cbSecDesc, &pDacl, &fDaclPresent, &DaclSizeInfo); if (pSecDesc) { /* * Create a new DACL. This will contain one extra ACE. */ PSECURITY_DESCRIPTOR pNewSecDesc = (PSECURITY_DESCRIPTOR)RTMemTmpAlloc(cbSecDesc); if ( pNewSecDesc && InitializeSecurityDescriptor(pNewSecDesc, SECURITY_DESCRIPTOR_REVISION)) { uint32_t const cbSid = GetLengthSid(pSid); uint32_t const cbNewDacl = DaclSizeInfo.AclBytesInUse + (sizeof(ACCESS_ALLOWED_ACE) + cbSid) * 1; PACL pNewDacl = (PACL)RTMemTmpAlloc(cbNewDacl); if ( pNewDacl && InitializeAcl(pNewDacl, cbNewDacl, ACL_REVISION) && rtProcWinCopyAces(pNewDacl, pDacl, fDaclPresent ? DaclSizeInfo.AceCount : 0)) { /* * Add the new SID ACE. */ if (rtProcWinAddAccessAllowedAce(pNewDacl, 0 /*fAceFlags*/, MY_DESKTOP_ALL_RIGHTS, pSid, cbSid)) { /* * Now mate the new DECL with the security descriptor and set it. */ if (SetSecurityDescriptorDacl(pNewSecDesc, TRUE /*fDaclPresent*/, pNewDacl, FALSE /*fDaclDefaulted*/)) { SECURITY_INFORMATION SecInfo = DACL_SECURITY_INFORMATION; if (SetUserObjectSecurity(hDesktop, &SecInfo, pNewSecDesc)) fRet = true; else AssertFailed(); } else AssertFailed(); } else AssertFailed(); } else AssertFailed(); RTMemTmpFree(pNewDacl); } else AssertFailed(); RTMemTmpFree(pNewSecDesc); RTMemTmpFree(pSecDesc); } return fRet; } /** * Preps the window station and desktop for the new app. * * EXPERIMENTAL. Thus no return code. * * @param hTokenToUse The access token of the new process. * @param pStartupInfo The startup info (we'll change lpDesktop, maybe). * @param phWinStationOld Where to return an window station handle to restore. * Pass this to SetProcessWindowStation if not NULL. */ static void rtProcWinStationPrep(HANDLE hTokenToUse, STARTUPINFOW *pStartupInfo, HWINSTA *phWinStationOld) { /** @todo Always mess with the interactive one? Maybe it's not there... */ *phWinStationOld = GetProcessWindowStation(); HWINSTA hWinStation0; if (g_pfnOpenWindowStationW) hWinStation0 = g_pfnOpenWindowStationW(L"winsta0", FALSE /*fInherit*/, READ_CONTROL | WRITE_DAC); else hWinStation0 = OpenWindowStationA("winsta0", FALSE /*fInherit*/, READ_CONTROL | WRITE_DAC); /* (for NT3.1) */ if (hWinStation0) { if (SetProcessWindowStation(hWinStation0)) { HDESK hDesktop = OpenDesktop("default", 0 /*fFlags*/, FALSE /*fInherit*/, READ_CONTROL | WRITE_DAC | DESKTOP_WRITEOBJECTS | DESKTOP_READOBJECTS); if (hDesktop) { /*PSID pSid = rtProcWinGetTokenLogonSid(hTokenToUse); - Better to use the user SID. Avoid overflowing the ACL. */ PSID pSid = rtProcWinGetTokenUserSid(hTokenToUse, NULL /*prc*/); if (pSid) { if ( rtProcWinAddSidToWinStation(hWinStation0, pSid) && rtProcWinAddSidToDesktop(hDesktop, pSid)) { pStartupInfo->lpDesktop = L"winsta0\\default"; } RTMemFree(pSid); } CloseDesktop(hDesktop); } else AssertFailed(); } else AssertFailed(); if (g_pfnCloseWindowStation) g_pfnCloseWindowStation(hWinStation0); } else AssertFailed(); } /** * Extracts the user name + domain from a given UPN (User Principal Name, "joedoe@example.com") or * Down-Level Logon Name format ("example.com\\joedoe") string. * * @return IPRT status code. * @param pwszString Pointer to string to extract the account info from. * @param pAccountInfo Where to store the parsed account info. * Must be free'd with rtProcWinFreeAccountInfo(). */ static int rtProcWinParseAccountInfo(PRTUTF16 pwszString, PRTPROCWINACCOUNTINFO pAccountInfo) { AssertPtrReturn(pwszString, VERR_INVALID_POINTER); AssertPtrReturn(pAccountInfo, VERR_INVALID_POINTER); /* * Note: UPN handling is defined in RFC 822. We only implement very rudimentary parsing for the user * name and domain fields though. */ char *pszString; int rc = RTUtf16ToUtf8(pwszString, &pszString); if (RT_SUCCESS(rc)) { do { /* UPN or FQDN handling needed? */ /** @todo Add more validation here as needed. Regular expressions would be nice. */ char *pszDelim = strchr(pszString, '@'); if (pszDelim) /* UPN name? */ { rc = RTStrToUtf16Ex(pszString, pszDelim - pszString, &pAccountInfo->pwszUserName, 0, NULL); if (RT_FAILURE(rc)) break; rc = RTStrToUtf16Ex(pszDelim + 1, RTSTR_MAX, &pAccountInfo->pwszDomain, 0, NULL); if (RT_FAILURE(rc)) break; } else if (pszDelim = strchr(pszString, '\\')) /* FQDN name? */ { rc = RTStrToUtf16Ex(pszString, pszDelim - pszString, &pAccountInfo->pwszDomain, 0, NULL); if (RT_FAILURE(rc)) break; rc = RTStrToUtf16Ex(pszDelim + 1, RTSTR_MAX, &pAccountInfo->pwszUserName, 0, NULL); if (RT_FAILURE(rc)) break; } else rc = VERR_NOT_SUPPORTED; } while (0); RTStrFree(pszString); } #ifdef DEBUG LogRelFunc(("Name : %ls\n", pAccountInfo->pwszUserName)); LogRelFunc(("Domain: %ls\n", pAccountInfo->pwszDomain)); #endif if (RT_FAILURE(rc)) LogRelFunc(("Parsing \"%ls\" failed with rc=%Rrc\n", pwszString, rc)); return rc; } static void rtProcWinFreeAccountInfo(PRTPROCWINACCOUNTINFO pAccountInfo) { if (!pAccountInfo) return; if (pAccountInfo->pwszUserName) { RTUtf16Free(pAccountInfo->pwszUserName); pAccountInfo->pwszUserName = NULL; } if (pAccountInfo->pwszDomain) { RTUtf16Free(pAccountInfo->pwszDomain); pAccountInfo->pwszDomain = NULL; } } /** * Tries to resolve the name of the SID. * * @returns IPRT status code. * @param pSid The SID to resolve. * @param ppwszName Where to return the name. Use RTUtf16Free to free. */ static int rtProcWinSidToName(PSID pSid, PRTUTF16 *ppwszName) { *ppwszName = NULL; /* * Use large initial buffers here to try avoid having to repeat the call. */ DWORD cwcAllocated = 512; while (cwcAllocated < _32K) { PRTUTF16 pwszName = RTUtf16Alloc(cwcAllocated * sizeof(RTUTF16)); AssertReturn(pwszName, VERR_NO_UTF16_MEMORY); PRTUTF16 pwszDomain = RTUtf16Alloc(cwcAllocated * sizeof(RTUTF16)); AssertReturnStmt(pwszDomain, RTUtf16Free(pwszName), VERR_NO_UTF16_MEMORY); DWORD cwcName = cwcAllocated; DWORD cwcDomain = cwcAllocated; SID_NAME_USE SidNameUse = SidTypeUser; if (LookupAccountSidW(NULL /*lpSystemName*/, pSid, pwszName, &cwcName, pwszDomain, &cwcDomain, &SidNameUse)) { *ppwszName = pwszName; RTUtf16Free(pwszDomain); /* may need this later. */ return VINF_SUCCESS; } DWORD const dwErr = GetLastError(); RTUtf16Free(pwszName); RTUtf16Free(pwszDomain); if (dwErr != ERROR_INSUFFICIENT_BUFFER) return RTErrConvertFromWin32(dwErr); cwcAllocated = RT_MAX(cwcName, cwcDomain) + 1; } return RTErrConvertFromWin32(ERROR_INSUFFICIENT_BUFFER); } /** * Tries to resolve the user name for the token. * * @returns IPRT status code. * @param hToken The token. * @param ppwszUser Where to return the username. Use RTUtf16Free to free. */ static int rtProcWinTokenToUsername(HANDLE hToken, PRTUTF16 *ppwszUser) { int rc = VINF_SUCCESS; PSID pSid = rtProcWinGetTokenUserSid(hToken, &rc); if (pSid) { rc = rtProcWinSidToName(pSid, ppwszUser); RTMemFree(pSid); } else *ppwszUser = NULL; return rc; } /** * Method \#2. * * @note pwszUser can be NULL when RTPROC_FLAGS_AS_IMPERSONATED_TOKEN is set. */ static int rtProcWinCreateAsUser2(PRTUTF16 pwszUser, PRTUTF16 pwszPassword, PRTUTF16 *ppwszExec, PRTUTF16 pwszCmdLine, RTENV hEnv, DWORD dwCreationFlags, STARTUPINFOW *pStartupInfo, PROCESS_INFORMATION *pProcInfo, uint32_t fFlags, const char *pszExec, uint32_t idDesiredSession, HANDLE hUserToken) { /* * So if we want to start a process from a service (RTPROC_FLAGS_SERVICE), * we have to do the following: * - Check the credentials supplied and get the user SID. * - If valid get the correct Explorer/VBoxTray instance corresponding to that * user. This of course is only possible if that user is logged in (over * physical console or terminal services). * - If we found the user's Explorer/VBoxTray app, use and modify the token to * use it in order to allow the newly started process to access the user's * desktop. If there's no Explorer/VBoxTray app we cannot display the started * process (but run it without UI). * * The following restrictions apply: * - A process only can show its UI when the user the process should run * under is logged in (has a desktop). * - We do not want to display a process of user A run on the desktop * of user B on multi session systems. * * The following rights are needed in order to use LogonUserW and * CreateProcessAsUserW, so the local policy has to be modified to: * - SE_TCB_NAME = Act as part of the operating system * - SE_ASSIGNPRIMARYTOKEN_NAME = Create/replace a (process) token object * - SE_INCREASE_QUOTA_NAME = Increase quotas * * We may fail here with ERROR_PRIVILEGE_NOT_HELD. */ DWORD dwErr = NO_ERROR; HANDLE hTokenLogon = INVALID_HANDLE_VALUE; int rc = VINF_SUCCESS; if (fFlags & RTPROC_FLAGS_TOKEN_SUPPLIED) hTokenLogon = hUserToken; else if (fFlags & RTPROC_FLAGS_AS_IMPERSONATED_TOKEN) rc = rtProcWinGetThreadTokenHandle(GetCurrentThread(), &hTokenLogon); else if (pwszUser == NULL) rc = rtProcWinGetProcessTokenHandle(GetCurrentProcess(), &hTokenLogon); else rc = rtProcWinUserLogon(pwszUser, pwszPassword, &hTokenLogon); if (RT_SUCCESS(rc)) { BOOL fRc; bool fFound = false; HANDLE hTokenUserDesktop = INVALID_HANDLE_VALUE; /* * If the SERVICE flag is specified, we do something rather ugly to * make things work at all. We search for a known desktop process * belonging to the user, grab its token and use it for launching * the new process. That way the process will have desktop access. */ if (fFlags & RTPROC_FLAGS_SERVICE) { /* * For the token search we need a SID. */ PSID pSid = rtProcWinGetTokenUserSid(hTokenLogon, &rc); /* * If we got a valid SID, search the running processes. */ /* * If we got a valid SID, search the running processes. */ if (pSid) { if (IsValidSid(pSid)) { /* Array of process names we want to look for. */ static const char * const s_papszProcNames[] = { #ifdef VBOX /* The explorer entry is a fallback in case GA aren't installed. */ { "VBoxTray.exe" }, # ifndef IN_GUEST { "VirtualBox.exe" }, # endif #endif { "explorer.exe" }, NULL }; fFound = rtProcWinFindTokenByProcess(s_papszProcNames, pSid, idDesiredSession, &hTokenUserDesktop); dwErr = 0; } else { dwErr = GetLastError(); LogRelFunc(("SID is invalid: %ld\n", dwErr)); rc = dwErr != NO_ERROR ? RTErrConvertFromWin32(dwErr) : VERR_INTERNAL_ERROR_3; } RTMemFree(pSid); } } /* else: !RTPROC_FLAGS_SERVICE: Nothing to do here right now. */ #if 0 /* * If we make LogonUserW to return an impersonation token, enable this * to convert it into a primary token. */ if (!fFound && detect-impersonation-token) { HANDLE hNewToken; if (DuplicateTokenEx(hTokenLogon, MAXIMUM_ALLOWED, NULL /*SecurityAttribs*/, SecurityIdentification, TokenPrimary, &hNewToken)) { CloseHandle(hTokenLogon); hTokenLogon = hNewToken; } else AssertMsgFailed(("%d\n", GetLastError())); } #endif if (RT_SUCCESS(rc)) { /* * If we didn't find a matching VBoxTray, just use the token we got * above from LogonUserW(). This enables us to at least run processes * with desktop interaction without UI. */ HANDLE hTokenToUse = fFound ? hTokenUserDesktop : hTokenLogon; if ( !(fFlags & RTPROC_FLAGS_PROFILE) || (g_pfnUnloadUserProfile && g_pfnLoadUserProfileW) ) { /* * Load the profile, if requested. (Must be done prior to creating the enviornment.) * * Note! We don't have sufficient rights when impersonating a user, but we can * ASSUME the user is logged on and has its profile loaded into HKEY_USERS already. */ PROFILEINFOW ProfileInfo; PRTUTF16 pwszUserFree = NULL; RT_ZERO(ProfileInfo); /** @todo r=bird: We probably don't need to load anything if pwszUser is NULL... */ if ((fFlags & (RTPROC_FLAGS_PROFILE | RTPROC_FLAGS_AS_IMPERSONATED_TOKEN)) == RTPROC_FLAGS_PROFILE) { if (!pwszUser) { Assert(fFlags & RTPROC_FLAGS_AS_IMPERSONATED_TOKEN); rc = rtProcWinTokenToUsername(hTokenToUse, &pwszUserFree); pwszUser = pwszUserFree; } if (RT_SUCCESS(rc)) { ProfileInfo.dwSize = sizeof(ProfileInfo); ProfileInfo.dwFlags = PI_NOUI; /* Prevents the display of profile error messages. */ ProfileInfo.lpUserName = pwszUser; if (!g_pfnLoadUserProfileW(hTokenToUse, &ProfileInfo)) rc = RTErrConvertFromWin32(GetLastError()); } } if (RT_SUCCESS(rc)) { /* * Create the environment. */ RTENV hEnvFinal; rc = rtProcWinCreateEnvFromToken(hTokenToUse, hEnv, fFlags, &hEnvFinal); if (RT_SUCCESS(rc)) { PRTUTF16 pwszzBlock; rc = RTEnvQueryUtf16Block(hEnvFinal, &pwszzBlock); if (RT_SUCCESS(rc)) { rc = rtProcWinFindExe(fFlags, hEnv, pszExec, ppwszExec); if (RT_SUCCESS(rc)) { HWINSTA hOldWinStation = NULL; if ( !fFound && g_enmWinVer <= kRTWinOSType_NT4) /** @todo test newer versions... */ rtProcWinStationPrep(hTokenToUse, pStartupInfo, &hOldWinStation); /* * Useful KB articles: * http://support.microsoft.com/kb/165194/ * http://support.microsoft.com/kb/184802/ * http://support.microsoft.com/kb/327618/ */ if (g_pfnCreateProcessAsUserW) { fRc = g_pfnCreateProcessAsUserW(hTokenToUse, *ppwszExec, pwszCmdLine, NULL, /* pProcessAttributes */ NULL, /* pThreadAttributes */ TRUE, /* fInheritHandles */ dwCreationFlags, /** @todo Warn about exceeding 8192 bytes * on XP and up. */ pwszzBlock, /* lpEnvironment */ NULL, /* pCurrentDirectory */ pStartupInfo, pProcInfo); if (fRc) rc = VINF_SUCCESS; else { dwErr = GetLastError(); if (dwErr == ERROR_PRIVILEGE_NOT_HELD) rc = rtProcWinFigureWhichPrivilegeNotHeld2(); else rc = RTErrConvertFromWin32(dwErr); } } else rc = VERR_NOT_SUPPORTED; if (hOldWinStation) SetProcessWindowStation(hOldWinStation); } RTEnvFreeUtf16Block(pwszzBlock); } if (hEnvFinal != hEnv) RTEnvDestroy(hEnvFinal); } if ((fFlags & RTPROC_FLAGS_PROFILE) && ProfileInfo.hProfile) { fRc = g_pfnUnloadUserProfile(hTokenToUse, ProfileInfo.hProfile); #ifdef RT_STRICT if (!fRc) { DWORD dwErr2 = GetLastError(); AssertMsgFailed(("Unloading user profile failed with error %u (%#x) - Are all handles closed? (dwErr=%u)", dwErr2, dwErr2, dwErr)); } #endif } if (pwszUserFree) RTUtf16Free(pwszUserFree); } } else rc = VERR_SYMBOL_NOT_FOUND; } /* Account lookup succeeded? */ if (hTokenUserDesktop != INVALID_HANDLE_VALUE) CloseHandle(hTokenUserDesktop); if ( !(fFlags & RTPROC_FLAGS_TOKEN_SUPPLIED) && hTokenLogon != INVALID_HANDLE_VALUE) CloseHandle(hTokenLogon); if (rc == VERR_UNRESOLVED_ERROR) LogRelFunc(("dwErr=%u (%#x), rc=%Rrc\n", dwErr, dwErr, rc)); } return rc; } /** * Plants a standard handle into a child process on older windows versions. * * This is only needed when using CreateProcessWithLogonW on older windows * versions. It would appear that newer versions of windows does this for us. * * @param hSrcHandle The source handle. * @param hDstProcess The child process handle. * @param offProcParamMember The offset to RTL_USER_PROCESS_PARAMETERS. * @param ppvDstProcParamCache Where where cached the address of * RTL_USER_PROCESS_PARAMETERS in the child. */ static void rtProcWinDupStdHandleIntoChild(HANDLE hSrcHandle, HANDLE hDstProcess, uint32_t offProcParamMember, PVOID *ppvDstProcParamCache) { if (hSrcHandle != NULL && hSrcHandle != INVALID_HANDLE_VALUE) { HANDLE hDstHandle; if (DuplicateHandle(GetCurrentProcess(), hSrcHandle, hDstProcess, &hDstHandle, 0 /*IgnoredDesiredAccess*/, FALSE /*fInherit*/, DUPLICATE_SAME_ACCESS)) { if (hSrcHandle == hDstHandle) return; if (!*ppvDstProcParamCache) { PROCESS_BASIC_INFORMATION BasicInfo; ULONG cbIgn; NTSTATUS rcNt = NtQueryInformationProcess(hDstProcess, ProcessBasicInformation, &BasicInfo, sizeof(BasicInfo), &cbIgn); if (NT_SUCCESS(rcNt)) { SIZE_T cbCopied = 0; if (!ReadProcessMemory(hDstProcess, (char *)BasicInfo.PebBaseAddress + RT_UOFFSETOF(PEB_COMMON, ProcessParameters), ppvDstProcParamCache, sizeof(*ppvDstProcParamCache), &cbCopied)) { AssertMsgFailed(("PebBaseAddress=%p %d\n", BasicInfo.PebBaseAddress, GetLastError())); *ppvDstProcParamCache = NULL; } } else AssertMsgFailed(("rcNt=%#x\n", rcNt)); } if (*ppvDstProcParamCache) { if (WriteProcessMemory(hDstProcess, (char *)*ppvDstProcParamCache + offProcParamMember, &hDstHandle, sizeof(hDstHandle), NULL)) return; } /* * Close the handle. */ HANDLE hSrcHandle2; if (DuplicateHandle(hDstProcess, hDstHandle, GetCurrentProcess(), &hSrcHandle2, 0 /*IgnoredDesiredAccess*/, FALSE /*fInherit*/, DUPLICATE_SAME_ACCESS | DUPLICATE_CLOSE_SOURCE)) CloseHandle(hSrcHandle2); else AssertMsgFailed(("hDstHandle=%p %u\n", hDstHandle, GetLastError())); } else AssertMsg(GetLastError() == ERROR_INVALID_PARAMETER, ("%u\n", GetLastError())); } } /** * Method \#1. * * This method requires Windows 2000 or later. It may fail if the process is * running under the SYSTEM account (like a service, ERROR_ACCESS_DENIED) on * newer platforms (however, this works on W2K!). */ static int rtProcWinCreateAsUser1(PRTUTF16 pwszUser, PRTUTF16 pwszPassword, PRTUTF16 *ppwszExec, PRTUTF16 pwszCmdLine, RTENV hEnv, DWORD dwCreationFlags, STARTUPINFOW *pStartupInfo, PROCESS_INFORMATION *pProcInfo, uint32_t fFlags, const char *pszExec) { /* The CreateProcessWithLogonW API was introduced with W2K and later. It uses a service for launching the process. */ if (!g_pfnCreateProcessWithLogonW) return VERR_SYMBOL_NOT_FOUND; /* * Create the environment block and find the executable first. * * We try to skip this when RTPROC_FLAGS_PROFILE is set so we can sidestep * potential missing TCB privilege issues when calling UserLogonW. At least * NT4 and W2K requires the trusted code base (TCB) privilege for logon use. * Passing pwszzBlock=NULL and LOGON_WITH_PROFILE means the child process * gets the environment specified by the user profile. */ int rc; PRTUTF16 pwszzBlock = NULL; /* Eliminating the path search flags simplifies things a little. */ if ( (fFlags & RTPROC_FLAGS_SEARCH_PATH) && (RTPathHasPath(pszExec) || RTPathExists(pszExec))) fFlags &= ~RTPROC_FLAGS_SEARCH_PATH; /* * No profile is simple, as is a user specified environment (no change record). */ if ( !(fFlags & RTPROC_FLAGS_PROFILE) || ( !(fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD) && hEnv != RTENV_DEFAULT)) rc = rtProcWinCreateEnvBlockAndFindExe(fFlags, hEnv, pszExec, &pwszzBlock, ppwszExec); /* * Default profile environment without changes or path searching we leave * to the service that implements the API. */ else if ( hEnv == RTENV_DEFAULT && !(fFlags & (RTPROC_FLAGS_ENV_CHANGE_RECORD | RTPROC_FLAGS_SEARCH_PATH))) { pwszzBlock = NULL; rc = VINF_SUCCESS; } /* * Otherwise, we need to get the user profile environment. */ else { RTENV hEnvToUse = NIL_RTENV; HANDLE hTokenLogon = INVALID_HANDLE_VALUE; rc = rtProcWinUserLogon(pwszUser, pwszPassword, &hTokenLogon); if (RT_SUCCESS(rc)) { /* CreateEnvFromToken docs says we should load the profile, though we haven't observed any difference when not doing it. Maybe it's only an issue with roaming profiles or something similar... */ PROFILEINFOW ProfileInfo; RT_ZERO(ProfileInfo); ProfileInfo.dwSize = sizeof(ProfileInfo); ProfileInfo.lpUserName = pwszUser; ProfileInfo.dwFlags = PI_NOUI; /* Prevents the display of profile error messages. */ if (g_pfnLoadUserProfileW(hTokenLogon, &ProfileInfo)) { /* * Do what we need to do. Don't keep any temp environment object. */ rc = rtProcWinCreateEnvFromToken(hTokenLogon, hEnv, fFlags, &hEnvToUse); if (RT_SUCCESS(rc)) { rc = rtProcWinFindExe(fFlags, hEnv, pszExec, ppwszExec); if (RT_SUCCESS(rc)) rc = RTEnvQueryUtf16Block(hEnvToUse, &pwszzBlock); if (hEnvToUse != hEnv) RTEnvDestroy(hEnvToUse); } if (!g_pfnUnloadUserProfile(hTokenLogon, ProfileInfo.hProfile)) AssertFailed(); } else rc = RTErrConvertFromWin32(GetLastError()); if (hTokenLogon != INVALID_HANDLE_VALUE) CloseHandle(hTokenLogon); } } if (RT_SUCCESS(rc)) { /* * Create the process. */ Assert(!(dwCreationFlags & CREATE_SUSPENDED)); bool const fCreatedSuspended = g_enmWinVer < kRTWinOSType_XP; BOOL fRc = g_pfnCreateProcessWithLogonW(pwszUser, NULL, /* lpDomain*/ pwszPassword, fFlags & RTPROC_FLAGS_PROFILE ? 1 /*LOGON_WITH_PROFILE*/ : 0, *ppwszExec, pwszCmdLine, dwCreationFlags | (fCreatedSuspended ? CREATE_SUSPENDED : 0), pwszzBlock, NULL, /* pCurrentDirectory */ pStartupInfo, pProcInfo); if (fRc) { if (!fCreatedSuspended) rc = VINF_SUCCESS; else { /* * Duplicate standard handles into the child process, we ignore failures here as it's * legal to have bad standard handle values and we cannot dup console I/O handles.* */ PVOID pvDstProcParamCache = NULL; rtProcWinDupStdHandleIntoChild(pStartupInfo->hStdInput, pProcInfo->hProcess, RT_UOFFSETOF(RTL_USER_PROCESS_PARAMETERS, StandardInput), &pvDstProcParamCache); rtProcWinDupStdHandleIntoChild(pStartupInfo->hStdOutput, pProcInfo->hProcess, RT_UOFFSETOF(RTL_USER_PROCESS_PARAMETERS, StandardOutput), &pvDstProcParamCache); rtProcWinDupStdHandleIntoChild(pStartupInfo->hStdError, pProcInfo->hProcess, RT_UOFFSETOF(RTL_USER_PROCESS_PARAMETERS, StandardError), &pvDstProcParamCache); if (ResumeThread(pProcInfo->hThread) != ~(DWORD)0) rc = VINF_SUCCESS; else rc = RTErrConvertFromWin32(GetLastError()); if (RT_FAILURE(rc)) { TerminateProcess(pProcInfo->hProcess, 127); CloseHandle(pProcInfo->hThread); CloseHandle(pProcInfo->hProcess); } } } else { DWORD dwErr = GetLastError(); rc = RTErrConvertFromWin32(dwErr); if (rc == VERR_UNRESOLVED_ERROR) LogRelFunc(("CreateProcessWithLogonW failed: dwErr=%u (%#x), rc=%Rrc\n", dwErr, dwErr, rc)); } if (pwszzBlock) RTEnvFreeUtf16Block(pwszzBlock); } return rc; } static int rtProcWinCreateAsUser(PRTUTF16 pwszUser, PRTUTF16 pwszPassword, PRTUTF16 *ppwszExec, PRTUTF16 pwszCmdLine, RTENV hEnv, DWORD dwCreationFlags, STARTUPINFOW *pStartupInfo, PROCESS_INFORMATION *pProcInfo, uint32_t fFlags, const char *pszExec, uint32_t idDesiredSession, HANDLE hUserToken) { /* * If we run as a service CreateProcessWithLogon will fail, so don't even * try it (because of Local System context). If we got an impersonated token * we should use, we also have to have to skip over this approach. * Note! This method is very slow on W2K. */ if (!(fFlags & (RTPROC_FLAGS_SERVICE | RTPROC_FLAGS_AS_IMPERSONATED_TOKEN | RTPROC_FLAGS_TOKEN_SUPPLIED))) { AssertPtr(pwszUser); int rc = rtProcWinCreateAsUser1(pwszUser, pwszPassword, ppwszExec, pwszCmdLine, hEnv, dwCreationFlags, pStartupInfo, pProcInfo, fFlags, pszExec); if (RT_SUCCESS(rc)) return rc; } return rtProcWinCreateAsUser2(pwszUser, pwszPassword, ppwszExec, pwszCmdLine, hEnv, dwCreationFlags, pStartupInfo, pProcInfo, fFlags, pszExec, idDesiredSession, hUserToken); } /** * RTPathTraverseList callback used by rtProcWinFindExe to locate the * executable. */ static DECLCALLBACK(int) rtPathFindExec(char const *pchPath, size_t cchPath, void *pvUser1, void *pvUser2) { const char *pszExec = (const char *)pvUser1; char *pszRealExec = (char *)pvUser2; int rc = RTPathJoinEx(pszRealExec, RTPATH_MAX, pchPath, cchPath, pszExec, RTSTR_MAX, RTPATH_STR_F_STYLE_HOST); if (RT_FAILURE(rc)) return rc; if (RTFileExists(pszRealExec)) return VINF_SUCCESS; return VERR_TRY_AGAIN; } /** * Locate the executable file if necessary. * * @returns IPRT status code. * @param pszExec The UTF-8 executable string passed in by the user. * @param fFlags The process creation flags pass in by the user. * @param hEnv The environment to get the path variabel from. * @param ppwszExec Pointer to the variable pointing to the UTF-16 * converted string. If we find something, the current * pointer will be free (RTUtf16Free) and * replaced by a new one. */ static int rtProcWinFindExe(uint32_t fFlags, RTENV hEnv, const char *pszExec, PRTUTF16 *ppwszExec) { /* * Return immediately if we're not asked to search, or if the file has a * path already or if it actually exists in the current directory. */ if ( !(fFlags & RTPROC_FLAGS_SEARCH_PATH) || RTPathHavePath(pszExec) || RTPathExists(pszExec) ) return VINF_SUCCESS; /* * Search the Path or PATH variable for the file. */ char *pszPath; if (RTEnvExistEx(hEnv, "PATH")) pszPath = RTEnvDupEx(hEnv, "PATH"); else if (RTEnvExistEx(hEnv, "Path")) pszPath = RTEnvDupEx(hEnv, "Path"); else return VERR_FILE_NOT_FOUND; char szRealExec[RTPATH_MAX]; int rc = RTPathTraverseList(pszPath, ';', rtPathFindExec, (void *)pszExec, &szRealExec[0]); RTStrFree(pszPath); if (RT_SUCCESS(rc)) { /* * Replace the executable string. */ RTPathWinFree(*ppwszExec); *ppwszExec = NULL; rc = RTPathWinFromUtf8(ppwszExec, szRealExec, 0 /*fFlags*/); } else if (rc == VERR_END_OF_STRING) rc = VERR_FILE_NOT_FOUND; return rc; } /** * Creates the UTF-16 environment block and, if necessary, find the executable. * * @returns IPRT status code. * @param fFlags The process creation flags pass in by the user. * @param hEnv The environment handle passed by the user. * @param pszExec See rtProcWinFindExe. * @param ppwszzBlock Where RTEnvQueryUtf16Block returns the block. * @param ppwszExec See rtProcWinFindExe. */ static int rtProcWinCreateEnvBlockAndFindExe(uint32_t fFlags, RTENV hEnv, const char *pszExec, PRTUTF16 *ppwszzBlock, PRTUTF16 *ppwszExec) { int rc; /* * In most cases, we just need to convert the incoming enviornment to a * UTF-16 environment block. */ RTENV hEnvToUse = NIL_RTENV; /* (MSC maybe used uninitialized) */ if ( !(fFlags & (RTPROC_FLAGS_PROFILE | RTPROC_FLAGS_ENV_CHANGE_RECORD)) || (hEnv == RTENV_DEFAULT && !(fFlags & RTPROC_FLAGS_PROFILE)) || (hEnv != RTENV_DEFAULT && !(fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD)) ) { hEnvToUse = hEnv; rc = VINF_SUCCESS; } else if (fFlags & RTPROC_FLAGS_PROFILE) { /* * We need to get the profile environment for the current user. */ Assert((fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD) || hEnv == RTENV_DEFAULT); AssertReturn(g_pfnCreateEnvironmentBlock && g_pfnDestroyEnvironmentBlock, VERR_SYMBOL_NOT_FOUND); AssertReturn(g_pfnLoadUserProfileW && g_pfnUnloadUserProfile, VERR_SYMBOL_NOT_FOUND); HANDLE hToken; if (OpenProcessToken(GetCurrentProcess(), TOKEN_QUERY | TOKEN_DUPLICATE | TOKEN_IMPERSONATE, &hToken)) { rc = rtProcWinCreateEnvFromToken(hToken, hEnv, fFlags, &hEnvToUse); CloseHandle(hToken); } else rc = RTErrConvertFromWin32(GetLastError()); } else { /* * Apply hEnv as a change record on top of the default environment. */ Assert(fFlags & RTPROC_FLAGS_ENV_CHANGE_RECORD); rc = RTEnvClone(&hEnvToUse, RTENV_DEFAULT); if (RT_SUCCESS(rc)) { rc = RTEnvApplyChanges(hEnvToUse, hEnv); if (RT_FAILURE(rc)) RTEnvDestroy(hEnvToUse); } } if (RT_SUCCESS(rc)) { /* * Query the UTF-16 environment block and locate the executable (if needed). */ rc = RTEnvQueryUtf16Block(hEnvToUse, ppwszzBlock); if (RT_SUCCESS(rc)) rc = rtProcWinFindExe(fFlags, hEnvToUse, pszExec, ppwszExec); if (hEnvToUse != hEnv) RTEnvDestroy(hEnvToUse); } return rc; } RTR3DECL(int) RTProcCreateEx(const char *pszExec, const char * const *papszArgs, RTENV hEnv, uint32_t fFlags, PCRTHANDLE phStdIn, PCRTHANDLE phStdOut, PCRTHANDLE phStdErr, const char *pszAsUser, const char *pszPassword, void *pvExtraData, PRTPROCESS phProcess) { /* * Input validation */ AssertPtrReturn(pszExec, VERR_INVALID_POINTER); AssertReturn(*pszExec, VERR_INVALID_PARAMETER); AssertReturn(!(fFlags & ~RTPROC_FLAGS_VALID_MASK), VERR_INVALID_PARAMETER); AssertReturn(!(fFlags & RTPROC_FLAGS_DETACHED) || !phProcess, VERR_INVALID_PARAMETER); AssertReturn(hEnv != NIL_RTENV, VERR_INVALID_PARAMETER); AssertPtrReturn(papszArgs, VERR_INVALID_PARAMETER); AssertPtrNullReturn(pszAsUser, VERR_INVALID_POINTER); AssertReturn(!pszAsUser || *pszAsUser, VERR_INVALID_PARAMETER); AssertReturn(!pszPassword || pszAsUser, VERR_INVALID_PARAMETER); AssertPtrNullReturn(pszPassword, VERR_INVALID_POINTER); /* Extra data: */ uint32_t idDesiredSession = UINT32_MAX; if ( (fFlags & (RTPROC_FLAGS_DESIRED_SESSION_ID | RTPROC_FLAGS_SERVICE)) == (RTPROC_FLAGS_DESIRED_SESSION_ID | RTPROC_FLAGS_SERVICE)) { AssertPtrReturn(pvExtraData, VERR_INVALID_POINTER); idDesiredSession = *(uint32_t *)pvExtraData; } else AssertReturn(!(fFlags & RTPROC_FLAGS_DESIRED_SESSION_ID), VERR_INVALID_FLAGS); HANDLE hUserToken = NULL; if (fFlags & RTPROC_FLAGS_TOKEN_SUPPLIED) hUserToken = *(HANDLE *)pvExtraData; /* * Initialize the globals. */ int rc = RTOnce(&g_rtProcWinInitOnce, rtProcWinInitOnce, NULL); AssertRCReturn(rc, rc); if ( pszAsUser || (fFlags & (RTPROC_FLAGS_PROFILE | RTPROC_FLAGS_SERVICE | RTPROC_FLAGS_AS_IMPERSONATED_TOKEN | RTPROC_FLAGS_TOKEN_SUPPLIED))) { rc = RTOnce(&g_rtProcWinResolveOnce, rtProcWinResolveOnce, NULL); AssertRCReturn(rc, rc); } /* * Get the file descriptors for the handles we've been passed. * * It seems there is no point in trying to convince a child process's CRT * that any of the standard file handles is non-TEXT. So, we don't... */ STARTUPINFOW StartupInfo; RT_ZERO(StartupInfo); StartupInfo.cb = sizeof(StartupInfo); StartupInfo.dwFlags = STARTF_USESTDHANDLES; #if 1 /* The CRT should keep the standard handles up to date. */ StartupInfo.hStdInput = GetStdHandle(STD_INPUT_HANDLE); StartupInfo.hStdOutput = GetStdHandle(STD_OUTPUT_HANDLE); StartupInfo.hStdError = GetStdHandle(STD_ERROR_HANDLE); #else StartupInfo.hStdInput = _get_osfhandle(0); StartupInfo.hStdOutput = _get_osfhandle(1); StartupInfo.hStdError = _get_osfhandle(2); #endif /* If we want to have a hidden process (e.g. not visible to * to the user) use the STARTUPINFO flags. */ if (fFlags & RTPROC_FLAGS_HIDDEN) { StartupInfo.dwFlags |= STARTF_USESHOWWINDOW; StartupInfo.wShowWindow = SW_HIDE; } PCRTHANDLE paHandles[3] = { phStdIn, phStdOut, phStdErr }; HANDLE *aphStds[3] = { &StartupInfo.hStdInput, &StartupInfo.hStdOutput, &StartupInfo.hStdError }; DWORD afInhStds[3] = { 0xffffffff, 0xffffffff, 0xffffffff }; HANDLE ahStdDups[3] = { INVALID_HANDLE_VALUE, INVALID_HANDLE_VALUE, INVALID_HANDLE_VALUE }; for (int i = 0; i < 3; i++) { if (paHandles[i]) { AssertPtrReturn(paHandles[i], VERR_INVALID_POINTER); switch (paHandles[i]->enmType) { case RTHANDLETYPE_FILE: { HANDLE hNativeFile = paHandles[i]->u.hFile != NIL_RTFILE ? (HANDLE)RTFileToNative(paHandles[i]->u.hFile) : INVALID_HANDLE_VALUE; if ( hNativeFile == *aphStds[i] && g_enmWinVer == kRTWinOSType_NT310) continue; *aphStds[i] = hNativeFile; break; } case RTHANDLETYPE_PIPE: *aphStds[i] = paHandles[i]->u.hPipe != NIL_RTPIPE ? (HANDLE)RTPipeToNative(paHandles[i]->u.hPipe) : INVALID_HANDLE_VALUE; if ( g_enmWinVer == kRTWinOSType_NT310 && *aphStds[i] == INVALID_HANDLE_VALUE) { AssertMsgReturn(RTPipeGetCreationInheritability(paHandles[i]->u.hPipe), ("%Rrc %p\n", rc, *aphStds[i]), VERR_INVALID_STATE); continue; } break; case RTHANDLETYPE_SOCKET: *aphStds[i] = paHandles[i]->u.hSocket != NIL_RTSOCKET ? (HANDLE)RTSocketToNative(paHandles[i]->u.hSocket) : INVALID_HANDLE_VALUE; break; default: AssertMsgFailedReturn(("%d: %d\n", i, paHandles[i]->enmType), VERR_INVALID_PARAMETER); } /* Get the inheritability of the handle. */ if (*aphStds[i] != INVALID_HANDLE_VALUE) { if (!g_pfnGetHandleInformation) afInhStds[i] = 0; /* No handle info on NT 3.1, so ASSUME it is not inheritable. */ else if (!g_pfnGetHandleInformation(*aphStds[i], &afInhStds[i])) { rc = RTErrConvertFromWin32(GetLastError()); AssertMsgFailedReturn(("%Rrc aphStds[%d] => %p paHandles[%d]={%d,%p}\n", rc, i, *aphStds[i], i, paHandles[i]->enmType, paHandles[i]->u.uInt), rc); } } } } /* * Set the inheritability any handles we're handing the child. * * Note! On NT 3.1 there is no SetHandleInformation, so we have to duplicate * the handles to make sure they are inherited by the child. */ rc = VINF_SUCCESS; for (int i = 0; i < 3; i++) if ( (afInhStds[i] != 0xffffffff) && !(afInhStds[i] & HANDLE_FLAG_INHERIT)) { if (!g_pfnSetHandleInformation) { if (DuplicateHandle(GetCurrentProcess(), *aphStds[i], GetCurrentProcess(), &ahStdDups[i], i == 0 ? GENERIC_READ : GENERIC_WRITE, TRUE /*fInheritHandle*/, DUPLICATE_SAME_ACCESS)) *aphStds[i] = ahStdDups[i]; else { rc = RTErrConvertFromWin32(GetLastError()); AssertMsgFailedBreak(("%Rrc aphStds[%u] => %p\n", rc, i, *aphStds[i])); } } else if (!g_pfnSetHandleInformation(*aphStds[i], HANDLE_FLAG_INHERIT, HANDLE_FLAG_INHERIT)) { rc = RTErrConvertFromWin32(GetLastError()); if (rc == VERR_INVALID_FUNCTION && g_enmWinVer == kRTWinOSType_NT310) rc = VINF_SUCCESS; else AssertMsgFailedBreak(("%Rrc aphStds[%u] => %p\n", rc, i, *aphStds[i])); } } /* * Create the command line and convert the executable name. */ PRTUTF16 pwszCmdLine = NULL; /* Shut up, MSC! */ if (RT_SUCCESS(rc)) rc = RTGetOptArgvToUtf16String(&pwszCmdLine, papszArgs, !(fFlags & RTPROC_FLAGS_UNQUOTED_ARGS) ? RTGETOPTARGV_CNV_QUOTE_MS_CRT : RTGETOPTARGV_CNV_UNQUOTED); if (RT_SUCCESS(rc)) { PRTUTF16 pwszExec; rc = RTPathWinFromUtf8(&pwszExec, pszExec, 0 /*fFlags*/); if (RT_SUCCESS(rc)) { /* * Get going... */ PROCESS_INFORMATION ProcInfo; RT_ZERO(ProcInfo); DWORD dwCreationFlags = CREATE_UNICODE_ENVIRONMENT; if (fFlags & RTPROC_FLAGS_DETACHED) dwCreationFlags |= DETACHED_PROCESS; if (fFlags & RTPROC_FLAGS_NO_WINDOW) dwCreationFlags |= CREATE_NO_WINDOW; /* * Only use the normal CreateProcess stuff if we have no user name * and we are not running from a (Windows) service. Otherwise use * the more advanced version in rtProcWinCreateAsUser(). */ if ( pszAsUser == NULL && !(fFlags & (RTPROC_FLAGS_SERVICE | RTPROC_FLAGS_AS_IMPERSONATED_TOKEN | RTPROC_FLAGS_TOKEN_SUPPLIED))) { /* Create the environment block first. */ PRTUTF16 pwszzBlock; rc = rtProcWinCreateEnvBlockAndFindExe(fFlags, hEnv, pszExec, &pwszzBlock, &pwszExec); if (RT_SUCCESS(rc)) { if (CreateProcessW(pwszExec, pwszCmdLine, NULL, /* pProcessAttributes */ NULL, /* pThreadAttributes */ TRUE, /* fInheritHandles */ dwCreationFlags, pwszzBlock, NULL, /* pCurrentDirectory */ &StartupInfo, &ProcInfo)) rc = VINF_SUCCESS; else rc = RTErrConvertFromWin32(GetLastError()); RTEnvFreeUtf16Block(pwszzBlock); } } else { /* * Convert the additional parameters and use a helper * function to do the actual work. */ PRTUTF16 pwszUser = NULL; if (pszAsUser) rc = RTStrToUtf16(pszAsUser, &pwszUser); if (RT_SUCCESS(rc)) { PRTUTF16 pwszPassword; rc = RTStrToUtf16(pszPassword ? pszPassword : "", &pwszPassword); if (RT_SUCCESS(rc)) { rc = rtProcWinCreateAsUser(pwszUser, pwszPassword, &pwszExec, pwszCmdLine, hEnv, dwCreationFlags, &StartupInfo, &ProcInfo, fFlags, pszExec, idDesiredSession, hUserToken); if (pwszPassword && *pwszPassword) RTMemWipeThoroughly(pwszPassword, RTUtf16Len(pwszPassword), 5); RTUtf16Free(pwszPassword); } RTUtf16Free(pwszUser); } } if (RT_SUCCESS(rc)) { CloseHandle(ProcInfo.hThread); if (phProcess) { /* * Add the process to the child process list so RTProcWait can reuse and close * the process handle, unless, of course, the caller has no intention waiting. */ if (!(fFlags & RTPROC_FLAGS_NO_WAIT)) rtProcWinAddPid(ProcInfo.dwProcessId, ProcInfo.hProcess); else CloseHandle(ProcInfo.hProcess); *phProcess = ProcInfo.dwProcessId; } else CloseHandle(ProcInfo.hProcess); rc = VINF_SUCCESS; } RTPathWinFree(pwszExec); } RTUtf16Free(pwszCmdLine); } if (g_pfnSetHandleInformation) { /* Undo any handle inherit changes. */ for (int i = 0; i < 3; i++) if ( (afInhStds[i] != 0xffffffff) && !(afInhStds[i] & HANDLE_FLAG_INHERIT)) { if ( !g_pfnSetHandleInformation(*aphStds[i], HANDLE_FLAG_INHERIT, 0) && ( GetLastError() != ERROR_INVALID_FUNCTION || g_enmWinVer != kRTWinOSType_NT310) ) AssertMsgFailed(("%Rrc %p\n", RTErrConvertFromWin32(GetLastError()), *aphStds[i])); } } else { /* Close handles duplicated for correct inheritance. */ for (int i = 0; i < 3; i++) if (ahStdDups[i] != INVALID_HANDLE_VALUE) CloseHandle(ahStdDups[i]); } return rc; } RTR3DECL(int) RTProcWait(RTPROCESS Process, unsigned fFlags, PRTPROCSTATUS pProcStatus) { AssertReturn(!(fFlags & ~(RTPROCWAIT_FLAGS_BLOCK | RTPROCWAIT_FLAGS_NOBLOCK)), VERR_INVALID_PARAMETER); int rc = RTOnce(&g_rtProcWinInitOnce, rtProcWinInitOnce, NULL); AssertRCReturn(rc, rc); /* * Try find the process among the ones we've spawned, otherwise, attempt * opening the specified process. */ HANDLE hOpenedProc = NULL; HANDLE hProcess = rtProcWinFindPid(Process); if (hProcess == NULL) { hProcess = hOpenedProc = OpenProcess(PROCESS_QUERY_INFORMATION | SYNCHRONIZE, FALSE, Process); if (hProcess == NULL) { DWORD dwErr = GetLastError(); if (dwErr == ERROR_INVALID_PARAMETER) return VERR_PROCESS_NOT_FOUND; return RTErrConvertFromWin32(dwErr); } } /* * Wait for it to terminate. */ DWORD Millies = fFlags == RTPROCWAIT_FLAGS_BLOCK ? INFINITE : 0; DWORD WaitRc = WaitForSingleObjectEx(hProcess, Millies, TRUE); while (WaitRc == WAIT_IO_COMPLETION) WaitRc = WaitForSingleObjectEx(hProcess, Millies, TRUE); switch (WaitRc) { /* * It has terminated. */ case WAIT_OBJECT_0: { DWORD dwExitCode; if (GetExitCodeProcess(hProcess, &dwExitCode)) { /** @todo the exit code can be special statuses. */ if (pProcStatus) { pProcStatus->enmReason = RTPROCEXITREASON_NORMAL; pProcStatus->iStatus = (int)dwExitCode; } if (hOpenedProc == NULL) rtProcWinRemovePid(Process); rc = VINF_SUCCESS; } else rc = RTErrConvertFromWin32(GetLastError()); break; } /* * It hasn't terminated just yet. */ case WAIT_TIMEOUT: rc = VERR_PROCESS_RUNNING; break; /* * Something went wrong... */ case WAIT_FAILED: rc = RTErrConvertFromWin32(GetLastError()); break; case WAIT_ABANDONED: AssertFailed(); rc = VERR_GENERAL_FAILURE; break; default: AssertMsgFailed(("WaitRc=%RU32\n", WaitRc)); rc = VERR_GENERAL_FAILURE; break; } if (hOpenedProc != NULL) CloseHandle(hOpenedProc); return rc; } RTR3DECL(int) RTProcWaitNoResume(RTPROCESS Process, unsigned fFlags, PRTPROCSTATUS pProcStatus) { /** @todo this isn't quite right. */ return RTProcWait(Process, fFlags, pProcStatus); } RTR3DECL(int) RTProcTerminate(RTPROCESS Process) { if (Process == NIL_RTPROCESS) return VINF_SUCCESS; int rc = RTOnce(&g_rtProcWinInitOnce, rtProcWinInitOnce, NULL); AssertRCReturn(rc, rc); /* * Try find the process among the ones we've spawned, otherwise, attempt * opening the specified process. */ HANDLE hProcess = rtProcWinFindPid(Process); if (hProcess != NULL) { if (!TerminateProcess(hProcess, 127)) rc = RTErrConvertFromWin32(GetLastError()); } else { hProcess = OpenProcess(PROCESS_TERMINATE, FALSE, Process); if (hProcess != NULL) { BOOL fRc = TerminateProcess(hProcess, 127); DWORD dwErr = GetLastError(); CloseHandle(hProcess); if (!fRc) rc = RTErrConvertFromWin32(dwErr); } } return rc; } RTR3DECL(uint64_t) RTProcGetAffinityMask(void) { DWORD_PTR dwProcessAffinityMask = 0xffffffff; DWORD_PTR dwSystemAffinityMask; BOOL fRc = GetProcessAffinityMask(GetCurrentProcess(), &dwProcessAffinityMask, &dwSystemAffinityMask); Assert(fRc); NOREF(fRc); return dwProcessAffinityMask; } RTR3DECL(int) RTProcQueryUsername(RTPROCESS hProcess, char *pszUser, size_t cbUser, size_t *pcbUser) { AssertReturn( (pszUser && cbUser > 0) || (!pszUser && !cbUser), VERR_INVALID_PARAMETER); AssertReturn(pcbUser || pszUser, VERR_INVALID_PARAMETER); int rc; if ( hProcess == NIL_RTPROCESS || hProcess == RTProcSelf()) { RTUTF16 wszUsername[UNLEN + 1]; DWORD cwcUsername = RT_ELEMENTS(wszUsername); if (GetUserNameW(&wszUsername[0], &cwcUsername)) { if (pszUser) { rc = RTUtf16ToUtf8Ex(wszUsername, cwcUsername, &pszUser, cbUser, pcbUser); if (pcbUser) *pcbUser += 1; } else { *pcbUser = RTUtf16CalcUtf8Len(wszUsername) + 1; rc = VERR_BUFFER_OVERFLOW; } } else rc = RTErrConvertFromWin32(GetLastError()); } else rc = VERR_NOT_SUPPORTED; return rc; } RTR3DECL(int) RTProcQueryUsernameA(RTPROCESS hProcess, char **ppszUser) { AssertPtrReturn(ppszUser, VERR_INVALID_POINTER); int rc; if ( hProcess == NIL_RTPROCESS || hProcess == RTProcSelf()) { RTUTF16 wszUsername[UNLEN + 1]; DWORD cwcUsername = RT_ELEMENTS(wszUsername); if (GetUserNameW(&wszUsername[0], &cwcUsername)) rc = RTUtf16ToUtf8(wszUsername, ppszUser); else rc = RTErrConvertFromWin32(GetLastError()); } else rc = VERR_NOT_SUPPORTED; return rc; }