//========= Copyright Valve Corporation, All rights reserved. ============// // // Purpose: Utility to interrogate and modify the data in the OSX IPC Server // // $NoKeywords: $ //============================================================================= // README:README // // This file implements the --wrap for ld on linux that lets file i/o api's // behave as if it were running on a case insensitive file system. Unfortunately, // this is needed by both steam2 and steam3. It was decided to check the source // into both locations, otherwise someone would find the .o and have no idea // where to go for the source if it was in the 'other' tree. Also, because this // needs to be linked into every elf binary, the .o is checked in for Steam3 so that it is // always available. In Steam2 it sits with the PosixWin32.cpp implementation and gets // compiled along side of it through the make system. If you are reading this in Steam3, // you will probably want to actually make your changes in steam2 and do a baseless merge // to the steam3 copy. // // HOWTO: Add a new function. Add the function with _WRAP to the makefiles as noted below. // Add the implementation to pathmatch.cpp - probably mimicking the existing functions. // Build steam2 and copy to matching steam3/client. Take the pathmatch.o from steam 2 // and check it in to steam3 (in the location noted below). Full rebuild (re-link really) // of steam3. Test steam and check in. // // If you are looking at updating this file, please update the following as needed: // // STEAM2.../Projects/GazelleProto/Client/Engine/obj/RELEASE_NORMAL/libsteam_linux/Common/Misc/pathmatch.o // This is where steam2 builds the pathmatch.o out to. // // STEAM2.../Projects/GazelleProto/Makefile.shlib.base - contains _WRAP references // STEAM2.../Projects/Common/Misc/pathmatch.cpp - Where the source is checked in, keep in sync with: // STEAM3.../src/common/pathmatch.cpp - should be identical to previous file, but discoverable in steam3. // STEAM3.../src/lib/linux32/release/pathmatch.o - steam3 checked in version // STEAM3.../src/devtools/makefile_base_posix.mak - look for the _WRAP references #ifdef LINUX #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // Enable to do pathmatch caching. Beware: this code isn't threadsafe. // #define DO_PATHMATCH_CACHE #ifdef UTF8_PATHMATCH #define strcasecmp utf8casecmp #endif static bool s_bShowDiag; #define DEBUG_MSG( ... ) if ( s_bShowDiag ) fprintf( stderr, ##__VA_ARGS__ ) #ifndef __arm__ #define DEBUG_BREAK() __asm__ __volatile__ ( "int $3" ) #else #define DEBUG_BREAK() #endif #define _COMPILE_TIME_ASSERT(pred) switch(0){case 0:case pred:;} #define WRAP( fn, ret, ... ) \ ret __real_##fn(__VA_ARGS__); \ ret __wrap_##fn(__VA_ARGS__) #define CALL( fn ) __real_##fn // Needed by pathmatch code extern "C" int __real_access(const char *pathname, int mode); extern "C" DIR *__real_opendir(const char *name); // UTF-8 work from PhysicsFS: http://icculus.org/physfs/ // Even if it wasn't under the zlib license, Ryan wrote all this code originally. #define UNICODE_BOGUS_CHAR_VALUE 0xFFFFFFFF #define UNICODE_BOGUS_CHAR_CODEPOINT '?' inline __attribute__ ((always_inline)) static uint32_t utf8codepoint(const char **_str) { const char *str = *_str; uint32_t retval = 0; uint32_t octet = (uint32_t) ((uint8_t) *str); uint32_t octet2, octet3, octet4; if (octet == 0) // null terminator, end of string. return 0; else if (octet < 128) // one octet char: 0 to 127 { (*_str)++; // skip to next possible start of codepoint. return octet; } else if ((octet > 127) && (octet < 192)) // bad (starts with 10xxxxxx). { // Apparently each of these is supposed to be flagged as a bogus // char, instead of just resyncing to the next valid codepoint. (*_str)++; // skip to next possible start of codepoint. return UNICODE_BOGUS_CHAR_VALUE; } else if (octet < 224) // two octets { octet -= (128+64); octet2 = (uint32_t) ((uint8_t) *(++str)); if ((octet2 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; *_str += 2; // skip to next possible start of codepoint. retval = ((octet << 6) | (octet2 - 128)); if ((retval >= 0x80) && (retval <= 0x7FF)) return retval; } else if (octet < 240) // three octets { octet -= (128+64+32); octet2 = (uint32_t) ((uint8_t) *(++str)); if ((octet2 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet3 = (uint32_t) ((uint8_t) *(++str)); if ((octet3 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; *_str += 3; // skip to next possible start of codepoint. retval = ( ((octet << 12)) | ((octet2-128) << 6) | ((octet3-128)) ); // There are seven "UTF-16 surrogates" that are illegal in UTF-8. switch (retval) { case 0xD800: case 0xDB7F: case 0xDB80: case 0xDBFF: case 0xDC00: case 0xDF80: case 0xDFFF: return UNICODE_BOGUS_CHAR_VALUE; } // 0xFFFE and 0xFFFF are illegal, too, so we check them at the edge. if ((retval >= 0x800) && (retval <= 0xFFFD)) return retval; } else if (octet < 248) // four octets { octet -= (128+64+32+16); octet2 = (uint32_t) ((uint8_t) *(++str)); if ((octet2 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet3 = (uint32_t) ((uint8_t) *(++str)); if ((octet3 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet4 = (uint32_t) ((uint8_t) *(++str)); if ((octet4 & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; *_str += 4; // skip to next possible start of codepoint. retval = ( ((octet << 18)) | ((octet2 - 128) << 12) | ((octet3 - 128) << 6) | ((octet4 - 128)) ); if ((retval >= 0x10000) && (retval <= 0x10FFFF)) return retval; } // Five and six octet sequences became illegal in rfc3629. // We throw the codepoint away, but parse them to make sure we move // ahead the right number of bytes and don't overflow the buffer. else if (octet < 252) // five octets { octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; *_str += 5; // skip to next possible start of codepoint. return UNICODE_BOGUS_CHAR_VALUE; } else // six octets { octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; octet = (uint32_t) ((uint8_t) *(++str)); if ((octet & (128+64)) != 128) // Format isn't 10xxxxxx? return UNICODE_BOGUS_CHAR_VALUE; *_str += 6; // skip to next possible start of codepoint. return UNICODE_BOGUS_CHAR_VALUE; } return UNICODE_BOGUS_CHAR_VALUE; } typedef struct CaseFoldMapping { uint32_t from; uint32_t to0; uint32_t to1; uint32_t to2; } CaseFoldMapping; typedef struct CaseFoldHashBucket { const uint8_t count; const CaseFoldMapping *list; } CaseFoldHashBucket; #include "pathmatch_casefolding.h" inline __attribute__ ((always_inline)) static void locate_case_fold_mapping(const uint32_t from, uint32_t *to) { const uint8_t hashed = ((from ^ (from >> 8)) & 0xFF); const CaseFoldHashBucket *bucket = &case_fold_hash[hashed]; const CaseFoldMapping *mapping = bucket->list; uint32_t i; for (i = 0; i < bucket->count; i++, mapping++) { if (mapping->from == from) { to[0] = mapping->to0; to[1] = mapping->to1; to[2] = mapping->to2; return; } } // Not found...there's no remapping for this codepoint. to[0] = from; to[1] = 0; to[2] = 0; } inline __attribute__ ((always_inline)) static uint32_t *fold_utf8(const char *str) { uint32_t *retval = new uint32_t[(strlen(str) * 3) + 1]; uint32_t *dst = retval; while (*str) { const char ch = *str; if (ch & 0x80) // high bit set? UTF-8 sequence! { uint32_t fold[3]; locate_case_fold_mapping(utf8codepoint(&str), fold); *(dst++) = fold[0]; if (fold[1]) { *(dst++) = fold[1]; if (fold[2]) *(dst++) = fold[2]; } } else // simple ASCII test. { *(dst++) = (uint32_t) (((ch >= 'A') && (ch <= 'Z')) ? ch + 32 : ch); str++; } } *dst = 0; return retval; } inline __attribute__ ((always_inline)) static int utf8casecmp_loop(const uint32_t *folded1, const uint32_t *folded2) { while (true) { const uint32_t ch1 = *(folded1++); const uint32_t ch2 = *(folded2++); if (ch1 < ch2) return -1; else if (ch1 > ch2) return 1; else if (ch1 == 0) return 0; // complete match. } } #ifdef UTF8_PATHMATCH static int utf8casecmp(const char *str1, const char *str2) { uint32_t *folded1 = fold_utf8(str1); uint32_t *folded2 = fold_utf8(str2); const int retval = utf8casecmp_loop(folded1, folded2); delete[] folded1; delete[] folded2; return retval; } #endif // Simple object to help make sure a DIR* from opendir // gets closed when it goes out of scope. class CDirPtr { public: CDirPtr() { m_pDir = NULL; } CDirPtr( DIR *pDir ) : m_pDir(pDir) {} ~CDirPtr() { Close(); } void operator=(DIR *pDir) { Close(); m_pDir = pDir; } operator DIR *() { return m_pDir; } operator bool() { return m_pDir != NULL; } private: void Close() { if ( m_pDir ) closedir( m_pDir ); } DIR *m_pDir; }; // Object used to temporarily slice a path into a smaller componentent // and then repair it when going out of scope. Typically used as an unnamed // temp object that is a parameter to a function. class CDirTrimmer { public: CDirTrimmer( char * pPath, size_t nTrimIdx ) { m_pPath = pPath; m_idx = nTrimIdx; m_c = m_pPath[nTrimIdx]; m_pPath[nTrimIdx] = '\0'; } ~CDirTrimmer() { m_pPath[m_idx] = m_c; } operator const char *() { return m_pPath; } private: size_t m_idx; char *m_pPath; char m_c; }; enum PathMod_t { kPathUnchanged, kPathLowered, kPathChanged, kPathFailed, }; static bool Descend( char *pPath, size_t nStartIdx, bool bAllowBasenameMismatch, size_t nLevel = 0 ) { DEBUG_MSG( "(%zu) Descend: %s, (%s), %s\n", nLevel, pPath, pPath+nStartIdx, bAllowBasenameMismatch ? "true" : "false " ); // We assume up through nStartIdx is valid and matching size_t nNextSlash = nStartIdx+1; // path might be a dir if ( pPath[nNextSlash] == '\0' ) { return true; } bool bIsDir = false; // is the new component a directory for certain? while ( pPath[nNextSlash] != '\0' && pPath[nNextSlash] != '/' ) { nNextSlash++; } // Modify the pPath string if ( pPath[nNextSlash] == '/' ) bIsDir = true; // See if we have an immediate match if ( __real_access( CDirTrimmer(pPath, nNextSlash), F_OK ) == 0 ) { if ( !bIsDir ) return true; bool bRet = Descend( pPath, nNextSlash, bAllowBasenameMismatch, nLevel+1 ); if ( bRet ) return true; } // Start enumerating dirents CDirPtr spDir; if ( nStartIdx ) { // we have a path spDir = __real_opendir( CDirTrimmer( pPath, nStartIdx ) ); nStartIdx++; } else { // we either start at root or cwd const char *pRoot = "."; if ( *pPath == '/' ) { pRoot = "/"; nStartIdx++; } spDir = __real_opendir( pRoot ); } errno = 0; struct dirent *pEntry = spDir ? readdir( spDir ) : NULL; char *pszComponent = pPath + nStartIdx; size_t cbComponent = nNextSlash - nStartIdx; while ( pEntry ) { DEBUG_MSG( "\t(%zu) comparing %s with %s\n", nLevel, pEntry->d_name, (const char *)CDirTrimmer(pszComponent, cbComponent) ); // the candidate must match the target, but not be a case-identical match (we would // have looked there in the short-circuit code above, so don't look again) bool bMatches = ( strcasecmp( CDirTrimmer(pszComponent, cbComponent), pEntry->d_name ) == 0 && strcmp( CDirTrimmer(pszComponent, cbComponent), pEntry->d_name ) != 0 ); if ( bMatches ) { char *pSrc = pEntry->d_name; char *pDst = &pPath[nStartIdx]; // found a match; copy it in. while ( *pSrc && (*pSrc != '/') ) { *pDst++ = *pSrc++; } if ( !bIsDir ) return true; if ( Descend( pPath, nNextSlash, bAllowBasenameMismatch, nLevel+1 ) ) return true; // If descend fails, try more directories } pEntry = readdir( spDir ); } if ( bIsDir ) { DEBUG_MSG( "(%zu) readdir failed to find '%s' in '%s'\n", nLevel, (const char *)CDirTrimmer(pszComponent, cbComponent), (const char *)CDirTrimmer( pPath, nStartIdx ) ); } // Sometimes it's ok for the filename portion to not match // since we might be opening for write. Note that if // the filename matches case insensitive, that will be // preferred over preserving the input name if ( !bIsDir && bAllowBasenameMismatch ) return true; return false; } #ifdef DO_PATHMATCH_CACHE typedef std::map > resultCache_t; typedef std::map >::iterator resultCacheItr_t; static resultCache_t resultCache; static const int k_cMaxCacheLifetimeSeconds = 2; #endif // DO_PATHMATCH_CACHE PathMod_t pathmatch( const char *pszIn, char **ppszOut, bool bAllowBasenameMismatch, char *pszOutBuf, size_t OutBufLen ) { // Path matching can be very expensive, and the cost is unpredictable because it // depends on how many files are in directories on a user's machine. Therefore // it should be disabled whenever possible, and only enabled in environments (such // as running with loose files such as out of Perforce) where it is needed. static const char *s_pszPathMatchEnabled = getenv("ENABLE_PATHMATCH"); if ( !s_pszPathMatchEnabled ) return kPathUnchanged; static const char *s_pszDbgPathMatch = getenv("DBG_PATHMATCH"); s_bShowDiag = ( s_pszDbgPathMatch != NULL ); *ppszOut = NULL; if ( __real_access( pszIn, F_OK ) == 0 ) return kPathUnchanged; #ifdef DO_PATHMATCH_CACHE resultCacheItr_t cachedResult = resultCache.find( pszIn ); if ( cachedResult != resultCache.end() ) { unsigned int age = time( NULL ) - cachedResult->second.second; const char *pszResult = cachedResult->second.first.c_str(); if ( pszResult[0] != '\0' || age <= k_cMaxCacheLifetimeSeconds ) { if ( pszResult[0] != '\0' ) { *ppszOut = strdup( pszResult ); DEBUG_MSG( "Cached '%s' -> '%s'\n", pszIn, *ppszOut ); return kPathChanged; } else { DEBUG_MSG( "Cached '%s' -> kPathFailed\n", pszIn ); return kPathFailed; } } else if ( age <= k_cMaxCacheLifetimeSeconds ) { DEBUG_MSG( "Rechecking '%s' - cache is %u seconds old\n", pszIn, age ); } } #endif // DO_PATHMATCH_CACHE char *pPath; if( strlen( pszIn ) >= OutBufLen ) { pPath = strdup( pszIn ); } else { strncpy( pszOutBuf, pszIn, OutBufLen ); pPath = pszOutBuf; } if ( pPath ) { // I believe this code is broken. I'm guessing someone wanted to avoid lowercasing // the path before the steam directory - but it's actually skipping lowercasing // whenever steam is found anywhere - including the filename. For example, // /home/mikesart/valvesrc/console/l4d2/game/left4dead2_dlc1/particles/steam_fx.pcf // winds up only having the "steam_fx.pcf" portion lowercased. #ifdef NEVER // optimization, if the path contained steam somewhere // assume the path up through the component with 'steam' in // is valid (because we almost certainly obtained it // progamatically char *p = strcasestr( pPath, "steam" ); if ( p ) { while ( p > pPath ) { if ( p[-1] == '/' ) break; p--; } if ( ( p == pPath+1 ) && ( *pPath != '/' ) ) p = pPath; } else { p = pPath; } #else char *p = pPath; #endif // Try the lower casing of the remaining path char *pBasename = p; while ( *p ) { if ( *p == '/' ) pBasename = p+1; *p = tolower(*p); p++; } if ( __real_access( pPath, F_OK ) == 0 ) { *ppszOut = pPath; DEBUG_MSG( "Lowered '%s' -> '%s'\n", pszIn, pPath ); return kPathLowered; } // path didn't match lowered successfully, restore the basename // if bAllowBasenameMismatch was true if ( bAllowBasenameMismatch ) { const char *pSrc = pszIn + (pBasename - pPath); while ( *pBasename ) { *pBasename++ = *pSrc++; } } if ( s_pszDbgPathMatch && strcasestr( s_pszDbgPathMatch, pszIn ) ) { DEBUG_MSG( "Breaking '%s' in '%s'\n", pszIn, s_pszDbgPathMatch ); DEBUG_BREAK(); } bool bSuccess = Descend( pPath, 0, bAllowBasenameMismatch ); if ( bSuccess ) { *ppszOut = pPath; DEBUG_MSG( "Matched '%s' -> '%s'\n", pszIn, pPath ); } else { DEBUG_MSG( "Unmatched %s\n", pszIn ); } #ifndef DO_PATHMATCH_CACHE return bSuccess ? kPathChanged : kPathFailed; #else time_t now = time(NULL); if ( bSuccess ) { resultCache[ pszIn ] = std::make_pair( *ppszOut, now ); return kPathChanged; } else { resultCache[ pszIn ] = std::make_pair( "", now ); return kPathFailed; } #endif } return kPathFailed; } // Wrapper object that manages the 'typical' usage cases of pathmatch() class CWrap { public: CWrap( const char *pSuppliedPath, bool bAllowMismatchedBasename ) : m_pSuppliedPath( pSuppliedPath ), m_pBestMatch( NULL ) { m_eResult = pathmatch( m_pSuppliedPath, &m_pBestMatch, bAllowMismatchedBasename, m_BestMatchBuf, sizeof( m_BestMatchBuf ) ); if ( m_pBestMatch == NULL ) { m_pBestMatch = const_cast( m_pSuppliedPath ); } } ~CWrap() { if ( ( m_pBestMatch != m_pSuppliedPath ) && ( m_pBestMatch != m_BestMatchBuf ) ) free( m_pBestMatch ); } const char *GetBest() const { return m_pBestMatch; } const char *GetOriginal() const { return m_pSuppliedPath; } PathMod_t GetMatchResult() const { return m_eResult; } operator const char*() { return GetBest(); } private: const char *m_pSuppliedPath; char *m_pBestMatch; char m_BestMatchBuf[ 512 ]; PathMod_t m_eResult; }; #ifdef MAIN_TEST void usage() { puts("pathmatch [options] "); //puts("options:"); //puts("\t"); exit(-1); } void test( const char *pszFile, bool bAllowBasenameMismatch ) { char *pNewPath; char NewPathBuf[ 512 ]; PathMod_t nStat = pathmatch( pszFile, &pNewPath, bAllowBasenameMismatch, NewPathBuf, sizeof( NewPathBuf ) ); printf("AllowMismatchedBasename: %s\n", bAllowBasenameMismatch ? "true" : "false" ); printf("Path Was: "); switch ( nStat ) { case kPathUnchanged: puts("kPathUnchanged"); break; case kPathLowered: puts("kPathLowered"); break; case kPathChanged: puts("kPathChanged"); break; case kPathFailed: puts("kPathFailed"); break; } printf(" Path In: %s\n", pszFile ); printf("Path Out: %s\n", nStat == kPathUnchanged ? pszFile : pNewPath ); if ( pNewPath ) free( pNewPath ); } int main(int argc, char **argv) { if ( argc <= 1 || argc > 2 ) usage(); test( argv[1], false ); test( argv[1], true ); return 0; } #endif extern "C" { WRAP(freopen, FILE *, const char *path, const char *mode, FILE *stream) { // if mode does not have w, a, or +, it's open for read. bool bAllowBasenameMismatch = strpbrk( mode, "wa+" ) != NULL; CWrap mpath( path, bAllowBasenameMismatch ); return CALL(freopen)( mpath, mode, stream ); } WRAP(fopen, FILE *, const char *path, const char *mode) { // if mode does not have w, a, or +, it's open for read. bool bAllowBasenameMismatch = strpbrk( mode, "wa+" ) != NULL; CWrap mpath( path, bAllowBasenameMismatch ); return CALL(fopen)( mpath, mode ); } #ifndef ANDROID WRAP(fopen64, FILE *, const char *path, const char *mode) { // if mode does not have w, a, or +, it's open for read. bool bAllowBasenameMismatch = strpbrk( mode, "wa+" ) != NULL; CWrap mpath( path, bAllowBasenameMismatch ); return CALL(fopen64)( mpath, mode ); } #endif WRAP(open, int, const char *pathname, int flags, mode_t mode) { bool bAllowBasenameMismatch = ((flags & (O_WRONLY | O_RDWR)) != 0); CWrap mpath( pathname, bAllowBasenameMismatch ); return CALL(open)( mpath, flags, mode ); } WRAP(open64, int, const char *pathname, int flags, mode_t mode) { bool bAllowBasenameMismatch = ((flags & (O_WRONLY | O_RDWR)) != 0); CWrap mpath( pathname, bAllowBasenameMismatch ); return CALL(open64)( mpath, flags, mode ); } int __wrap_creat(const char *pathname, mode_t mode) { return __wrap_open( pathname, O_CREAT|O_WRONLY|O_TRUNC, mode ); } int __wrap_access(const char *pathname, int mode) { return __real_access( CWrap( pathname, false ), mode ); } WRAP(stat, int, const char *path, struct stat *buf) { return CALL(stat)( CWrap( path, false ), buf ); } WRAP(lstat, int, const char *path, struct stat *buf) { return CALL(lstat)( CWrap( path, false ), buf ); } WRAP(scandir, int, const char *dirp, struct dirent ***namelist, int (*filter)(const struct dirent *), int (*compar)(const struct dirent **, const struct dirent **)) { return CALL(scandir)( CWrap( dirp, false ), namelist, filter, compar ); } WRAP(opendir, DIR*, const char *name) { return CALL(opendir)( CWrap( name, false ) ); } #ifndef ANDROID WRAP(__xstat, int, int __ver, __const char *__filename, struct stat *__stat_buf) { return CALL(__xstat)( __ver, CWrap( __filename, false), __stat_buf ); } WRAP(__lxstat, int, int __ver, __const char *__filename, struct stat *__stat_buf) { return CALL(__lxstat)( __ver, CWrap( __filename, false), __stat_buf ); } WRAP(__xstat64, int, int __ver, __const char *__filename, struct stat *__stat_buf) { return CALL(__xstat64)( __ver, CWrap( __filename, false), __stat_buf ); } WRAP(__lxstat64, int, int __ver, __const char *__filename, struct stat *__stat_buf) { return CALL(__lxstat64)( __ver, CWrap( __filename, false), __stat_buf ); } #endif WRAP(chmod, int, const char *path, mode_t mode) { return CALL(chmod)( CWrap( path, false), mode ); } WRAP(chown, int, const char *path, uid_t owner, gid_t group) { return CALL(chown)( CWrap( path, false), owner, group ); } WRAP(lchown, int, const char *path, uid_t owner, gid_t group) { return CALL(lchown)( CWrap( path, false), owner, group ); } WRAP(symlink, int, const char *oldpath, const char *newpath) { return CALL(symlink)( CWrap( oldpath, false), CWrap( newpath, true ) ); } WRAP(link, int, const char *oldpath, const char *newpath) { return CALL(link)( CWrap( oldpath, false), CWrap( newpath, true ) ); } WRAP(mknod, int, const char *pathname, mode_t mode, dev_t dev) { return CALL(mknod)( CWrap( pathname, true), mode, dev ); } WRAP(mount, int, const char *source, const char *target, const char *filesystemtype, unsigned long mountflags, const void *data) { return CALL(mount)( CWrap( source, false ), CWrap( target, false ), filesystemtype, mountflags, data ); } WRAP(unlink, int, const char *pathname) { return CALL(unlink)( CWrap( pathname, false ) ); } WRAP(mkfifo, int, const char *pathname, mode_t mode) { return CALL(mkfifo)( CWrap( pathname, true ), mode ); } WRAP(rename, int, const char *oldpath, const char *newpath) { return CALL(rename)( CWrap( oldpath, false), CWrap( newpath, true ) ); } WRAP(utime, int, const char *filename, const struct utimbuf *times) { return CALL(utime)( CWrap( filename, false), times ); } WRAP(utimes, int, const char *filename, const struct timeval times[2]) { return CALL(utimes)( CWrap( filename, false), times ); } WRAP(realpath, char *, const char *path, char *resolved_path) { return CALL(realpath)( CWrap( path, true ), resolved_path ); } WRAP(mkdir, int, const char *pathname, mode_t mode) { return CALL(mkdir)( CWrap( pathname, true ), mode ); } WRAP(rmdir, char *, const char *pathname) { return CALL(rmdir)( CWrap( pathname, false ) ); } }; #endif