/* * Copyright (c) 1993, Intergraph Corporation * * You may distribute under the terms of either the GNU General Public * License or the Artistic License, as specified in the perl README file. * * Various Unix compatibility functions and NT specific functions. * * Some of this code was derived from the MSDOS port(s) and the OS/2 port. * */ #include "ruby/ruby.h" #include "ruby/encoding.h" #include "dln.h" #include #include #include /* #include */ #include #include #include #include #include #include #include #include #include #include #include #if _MSC_VER >= 1400 #include #include #endif #ifdef __MINGW32__ #include #endif #include "ruby/win32.h" #include "win32/dir.h" #define isdirsep(x) ((x) == '/' || (x) == '\\') #undef stat #undef fclose #undef close #undef setsockopt #if defined __BORLANDC__ # define _filbuf _fgetc # define _flsbuf _fputc # define enough_to_get(n) (--(n) >= 0) # define enough_to_put(n) (++(n) < 0) #else # define enough_to_get(n) (--(n) >= 0) # define enough_to_put(n) (--(n) >= 0) #endif #ifdef WIN32_DEBUG #define Debug(something) something #else #define Debug(something) /* nothing */ #endif #define TO_SOCKET(x) _get_osfhandle(x) static struct ChildRecord *CreateChild(const char *, const char *, SECURITY_ATTRIBUTES *, HANDLE, HANDLE, HANDLE); static int has_redirection(const char *); int rb_w32_wait_events(HANDLE *events, int num, DWORD timeout); static int rb_w32_open_osfhandle(intptr_t osfhandle, int flags); #define RUBY_CRITICAL(expr) do { expr; } while (0) /* errno mapping */ static struct { DWORD winerr; int err; } errmap[] = { { ERROR_INVALID_FUNCTION, EINVAL }, { ERROR_FILE_NOT_FOUND, ENOENT }, { ERROR_PATH_NOT_FOUND, ENOENT }, { ERROR_TOO_MANY_OPEN_FILES, EMFILE }, { ERROR_ACCESS_DENIED, EACCES }, { ERROR_INVALID_HANDLE, EBADF }, { ERROR_ARENA_TRASHED, ENOMEM }, { ERROR_NOT_ENOUGH_MEMORY, ENOMEM }, { ERROR_INVALID_BLOCK, ENOMEM }, { ERROR_BAD_ENVIRONMENT, E2BIG }, { ERROR_BAD_FORMAT, ENOEXEC }, { ERROR_INVALID_ACCESS, EINVAL }, { ERROR_INVALID_DATA, EINVAL }, { ERROR_INVALID_DRIVE, ENOENT }, { ERROR_CURRENT_DIRECTORY, EACCES }, { ERROR_NOT_SAME_DEVICE, EXDEV }, { ERROR_NO_MORE_FILES, ENOENT }, { ERROR_WRITE_PROTECT, EROFS }, { ERROR_BAD_UNIT, ENODEV }, { ERROR_NOT_READY, ENXIO }, { ERROR_BAD_COMMAND, EACCES }, { ERROR_CRC, EACCES }, { ERROR_BAD_LENGTH, EACCES }, { ERROR_SEEK, EIO }, { ERROR_NOT_DOS_DISK, EACCES }, { ERROR_SECTOR_NOT_FOUND, EACCES }, { ERROR_OUT_OF_PAPER, EACCES }, { ERROR_WRITE_FAULT, EIO }, { ERROR_READ_FAULT, EIO }, { ERROR_GEN_FAILURE, EACCES }, { ERROR_LOCK_VIOLATION, EACCES }, { ERROR_SHARING_VIOLATION, EACCES }, { ERROR_WRONG_DISK, EACCES }, { ERROR_SHARING_BUFFER_EXCEEDED, EACCES }, { ERROR_BAD_NETPATH, ENOENT }, { ERROR_NETWORK_ACCESS_DENIED, EACCES }, { ERROR_BAD_NET_NAME, ENOENT }, { ERROR_FILE_EXISTS, EEXIST }, { ERROR_CANNOT_MAKE, EACCES }, { ERROR_FAIL_I24, EACCES }, { ERROR_INVALID_PARAMETER, EINVAL }, { ERROR_NO_PROC_SLOTS, EAGAIN }, { ERROR_DRIVE_LOCKED, EACCES }, { ERROR_BROKEN_PIPE, EPIPE }, { ERROR_DISK_FULL, ENOSPC }, { ERROR_INVALID_TARGET_HANDLE, EBADF }, { ERROR_INVALID_HANDLE, EINVAL }, { ERROR_WAIT_NO_CHILDREN, ECHILD }, { ERROR_CHILD_NOT_COMPLETE, ECHILD }, { ERROR_DIRECT_ACCESS_HANDLE, EBADF }, { ERROR_NEGATIVE_SEEK, EINVAL }, { ERROR_SEEK_ON_DEVICE, EACCES }, { ERROR_DIR_NOT_EMPTY, ENOTEMPTY }, { ERROR_DIRECTORY, ENOTDIR }, { ERROR_NOT_LOCKED, EACCES }, { ERROR_BAD_PATHNAME, ENOENT }, { ERROR_MAX_THRDS_REACHED, EAGAIN }, { ERROR_LOCK_FAILED, EACCES }, { ERROR_ALREADY_EXISTS, EEXIST }, { ERROR_INVALID_STARTING_CODESEG, ENOEXEC }, { ERROR_INVALID_STACKSEG, ENOEXEC }, { ERROR_INVALID_MODULETYPE, ENOEXEC }, { ERROR_INVALID_EXE_SIGNATURE, ENOEXEC }, { ERROR_EXE_MARKED_INVALID, ENOEXEC }, { ERROR_BAD_EXE_FORMAT, ENOEXEC }, { ERROR_ITERATED_DATA_EXCEEDS_64k,ENOEXEC }, { ERROR_INVALID_MINALLOCSIZE, ENOEXEC }, { ERROR_DYNLINK_FROM_INVALID_RING,ENOEXEC }, { ERROR_IOPL_NOT_ENABLED, ENOEXEC }, { ERROR_INVALID_SEGDPL, ENOEXEC }, { ERROR_AUTODATASEG_EXCEEDS_64k, ENOEXEC }, { ERROR_RING2SEG_MUST_BE_MOVABLE, ENOEXEC }, { ERROR_RELOC_CHAIN_XEEDS_SEGLIM, ENOEXEC }, { ERROR_INFLOOP_IN_RELOC_CHAIN, ENOEXEC }, { ERROR_FILENAME_EXCED_RANGE, ENOENT }, { ERROR_NESTING_NOT_ALLOWED, EAGAIN }, #ifndef ERROR_PIPE_LOCAL #define ERROR_PIPE_LOCAL 229L #endif { ERROR_PIPE_LOCAL, EPIPE }, { ERROR_BAD_PIPE, EPIPE }, { ERROR_PIPE_BUSY, EAGAIN }, { ERROR_NO_DATA, EPIPE }, { ERROR_PIPE_NOT_CONNECTED, EPIPE }, { ERROR_OPERATION_ABORTED, EINTR }, { ERROR_NOT_ENOUGH_QUOTA, ENOMEM }, { ERROR_MOD_NOT_FOUND, ENOENT }, { WSAENAMETOOLONG, ENAMETOOLONG }, { WSAENOTEMPTY, ENOTEMPTY }, { WSAEINTR, EINTR }, { WSAEBADF, EBADF }, { WSAEACCES, EACCES }, { WSAEFAULT, EFAULT }, { WSAEINVAL, EINVAL }, { WSAEMFILE, EMFILE }, }; int rb_w32_map_errno(DWORD winerr) { int i; if (winerr == 0) { return 0; } for (i = 0; i < (int)(sizeof(errmap) / sizeof(*errmap)); i++) { if (errmap[i].winerr == winerr) { return errmap[i].err; } } if (winerr >= WSABASEERR) { return winerr; } return EINVAL; } #define map_errno rb_w32_map_errno static const char *NTLoginName; static OSVERSIONINFO osver; static void get_version(void) { memset(&osver, 0, sizeof(OSVERSIONINFO)); osver.dwOSVersionInfoSize = sizeof(OSVERSIONINFO); GetVersionEx(&osver); } #ifdef _M_IX86 DWORD rb_w32_osid(void) { return osver.dwPlatformId; } #endif static DWORD rb_w32_osver(void) { return osver.dwMajorVersion; } #define IsWinNT() rb_w32_iswinnt() #define IsWin95() rb_w32_iswin95() #ifdef WIN95 #define IfWin95(win95, winnt) (IsWin95() ? (win95) : (winnt)) #else #define IfWin95(win95, winnt) (winnt) #endif HANDLE GetCurrentThreadHandle(void) { static HANDLE current_process_handle = NULL; HANDLE h; if (!current_process_handle) current_process_handle = GetCurrentProcess(); if (!DuplicateHandle(current_process_handle, GetCurrentThread(), current_process_handle, &h, 0, FALSE, DUPLICATE_SAME_ACCESS)) return NULL; return h; } /* simulate flock by locking a range on the file */ #define LK_ERR(f,i) \ do { \ if (f) \ i = 0; \ else { \ DWORD err = GetLastError(); \ if (err == ERROR_LOCK_VIOLATION || err == ERROR_IO_PENDING) \ errno = EWOULDBLOCK; \ else if (err == ERROR_NOT_LOCKED) \ i = 0; \ else \ errno = map_errno(err); \ } \ } while (0) #define LK_LEN ULONG_MAX static uintptr_t flock_winnt(uintptr_t self, int argc, uintptr_t* argv) { OVERLAPPED o; int i = -1; const HANDLE fh = (HANDLE)self; const int oper = argc; memset(&o, 0, sizeof(o)); switch(oper) { case LOCK_SH: /* shared lock */ LK_ERR(LockFileEx(fh, 0, 0, LK_LEN, LK_LEN, &o), i); break; case LOCK_EX: /* exclusive lock */ LK_ERR(LockFileEx(fh, LOCKFILE_EXCLUSIVE_LOCK, 0, LK_LEN, LK_LEN, &o), i); break; case LOCK_SH|LOCK_NB: /* non-blocking shared lock */ LK_ERR(LockFileEx(fh, LOCKFILE_FAIL_IMMEDIATELY, 0, LK_LEN, LK_LEN, &o), i); break; case LOCK_EX|LOCK_NB: /* non-blocking exclusive lock */ LK_ERR(LockFileEx(fh, LOCKFILE_EXCLUSIVE_LOCK|LOCKFILE_FAIL_IMMEDIATELY, 0, LK_LEN, LK_LEN, &o), i); break; case LOCK_UN: /* unlock lock */ case LOCK_UN|LOCK_NB: /* unlock is always non-blocking, I hope */ LK_ERR(UnlockFileEx(fh, 0, LK_LEN, LK_LEN, &o), i); break; default: /* unknown */ errno = EINVAL; break; } return i; } #ifdef WIN95 static uintptr_t flock_win95(uintptr_t self, int argc, uintptr_t* argv) { int i = -1; const HANDLE fh = (HANDLE)self; const int oper = argc; switch(oper) { case LOCK_EX: do { LK_ERR(LockFile(fh, 0, 0, LK_LEN, LK_LEN), i); } while (i && errno == EWOULDBLOCK); break; case LOCK_EX|LOCK_NB: LK_ERR(LockFile(fh, 0, 0, LK_LEN, LK_LEN), i); break; case LOCK_UN: case LOCK_UN|LOCK_NB: LK_ERR(UnlockFile(fh, 0, 0, LK_LEN, LK_LEN), i); break; default: errno = EINVAL; break; } return i; } #endif #undef LK_ERR int flock(int fd, int oper) { #ifdef WIN95 static asynchronous_func_t locker = NULL; if (!locker) { if (IsWinNT()) locker = flock_winnt; else locker = flock_win95; } #else const asynchronous_func_t locker = flock_winnt; #endif return rb_w32_asynchronize(locker, (VALUE)_get_osfhandle(fd), oper, NULL, (DWORD)-1); } static inline WCHAR * translate_wchar(WCHAR *p, int from, int to) { for (; *p; p++) { if (*p == from) *p = to; } return p; } static inline char * translate_char(char *p, int from, int to) { while (*p) { if ((unsigned char)*p == from) *p = to; p = CharNext(p); } return p; } #ifndef CSIDL_LOCAL_APPDATA #define CSIDL_LOCAL_APPDATA 28 #endif #ifndef CSIDL_COMMON_APPDATA #define CSIDL_COMMON_APPDATA 35 #endif #ifndef CSIDL_WINDOWS #define CSIDL_WINDOWS 36 #endif #ifndef CSIDL_SYSTEM #define CSIDL_SYSTEM 37 #endif #ifndef CSIDL_PROFILE #define CSIDL_PROFILE 40 #endif static BOOL get_special_folder(int n, WCHAR *env) { LPITEMIDLIST pidl; LPMALLOC alloc; BOOL f = FALSE; if (SHGetSpecialFolderLocation(NULL, n, &pidl) == 0) { f = SHGetPathFromIDListW(pidl, env); SHGetMalloc(&alloc); alloc->lpVtbl->Free(alloc, pidl); alloc->lpVtbl->Release(alloc); } return f; } static void regulate_path(WCHAR *path) { WCHAR *p = translate_wchar(path, L'\\', L'/'); if (p - path == 2 && path[1] == L':') { *p++ = L'/'; *p = L'\0'; } } static UINT get_system_directory(WCHAR *path, UINT len) { HANDLE hKernel = GetModuleHandle("kernel32.dll"); if (hKernel) { typedef UINT WINAPI wgetdir_func(WCHAR*, UINT); FARPROC ptr = GetProcAddress(hKernel, "GetSystemWindowsDirectoryW"); if (ptr) { return (*(wgetdir_func *)ptr)(path, len); } } return GetWindowsDirectoryW(path, len); } #define numberof(array) (sizeof(array) / sizeof(*array)) static void init_env(void) { static const WCHAR TMPDIR[] = L"TMPDIR"; WCHAR env[_MAX_PATH]; WCHAR *buf; DWORD len; BOOL f; if (!GetEnvironmentVariableW(L"HOME", env, numberof(env))) { f = FALSE; if (GetEnvironmentVariableW(L"HOMEDRIVE", env, numberof(env))) len = lstrlenW(env); else len = 0; if (GetEnvironmentVariableW(L"HOMEPATH", env + len, numberof(env) - len) || len) { f = TRUE; } else if (GetEnvironmentVariableW(L"USERPROFILE", env, numberof(env))) { f = TRUE; } else if (get_special_folder(CSIDL_PROFILE, env)) { f = TRUE; } else if (get_special_folder(CSIDL_PERSONAL, env)) { f = TRUE; } if (f) { regulate_path(env); buf = ALLOCA_N(WCHAR, 5 + lstrlenW(env) + 1); wsprintfW(buf, L"HOME=%s", env); _wputenv(buf); } } if (!GetEnvironmentVariableW(L"USER", env, numberof(env))) { if (!GetEnvironmentVariableW(L"USERNAME", env, numberof(env)) && !GetUserNameW(env, (len = numberof(env), &len))) { NTLoginName = ""; return; } buf = ALLOCA_N(WCHAR, 5 + lstrlenW(env) + 1); wsprintfW(buf, L"USER=%s", env); _wputenv(buf); } NTLoginName = strdup(rb_w32_getenv("USER")); if (!GetEnvironmentVariableW(TMPDIR, env, numberof(env)) && !GetEnvironmentVariableW(L"TMP", env, numberof(env)) && !GetEnvironmentVariableW(L"TEMP", env, numberof(env)) && (get_special_folder(CSIDL_LOCAL_APPDATA, env) || get_system_directory(env, numberof(env)))) { static const WCHAR temp[] = L"temp"; WCHAR *p = translate_wchar(env, L'\\', L'/'); if (*(p - 1) != L'/') *p++ = L'/'; if (p - env + numberof(temp) < numberof(env)) { memcpy(p, temp, sizeof(temp)); buf = ALLOCA_N(WCHAR, lstrlenW(TMPDIR) + 1 + lstrlenW(env) + 1); wsprintfW(buf, L"%s=%s", TMPDIR, env); _wputenv(buf); } } } typedef BOOL (WINAPI *cancel_io_t)(HANDLE); static cancel_io_t cancel_io = NULL; static void init_func(void) { if (!cancel_io) cancel_io = (cancel_io_t)GetProcAddress(GetModuleHandle("kernel32"), "CancelIo"); } static void init_stdhandle(void); #if RT_VER >= 80 static void invalid_parameter(const wchar_t *expr, const wchar_t *func, const wchar_t *file, unsigned int line, uintptr_t dummy) { // nothing to do } int ruby_w32_rtc_error; static int __cdecl rtc_error_handler(int e, const char *src, int line, const char *exe, const char *fmt, ...) { va_list ap; VALUE str; if (!ruby_w32_rtc_error) return 0; str = rb_sprintf("%s:%d: ", src, line); va_start(ap, fmt); rb_str_vcatf(str, fmt, ap); va_end(ap); rb_str_cat(str, "\n", 1); rb_write_error2(RSTRING_PTR(str), RSTRING_LEN(str)); return 0; } #endif static CRITICAL_SECTION select_mutex; static int NtSocketsInitialized = 0; static st_table *socklist = NULL; static char *envarea; static void exit_handler(void) { if (NtSocketsInitialized) { WSACleanup(); st_free_table(socklist); socklist = NULL; NtSocketsInitialized = 0; } if (envarea) { FreeEnvironmentStrings(envarea); envarea = NULL; } DeleteCriticalSection(&select_mutex); } static void StartSockets(void) { WORD version; WSADATA retdata; // // initalize the winsock interface and insure that it's // cleaned up at exit. // version = MAKEWORD(2, 0); if (WSAStartup(version, &retdata)) rb_fatal ("Unable to locate winsock library!\n"); if (LOBYTE(retdata.wVersion) != 2) rb_fatal("could not find version 2 of winsock dll\n"); socklist = st_init_numtable(); NtSocketsInitialized = 1; } // // Initialization stuff // void rb_w32_sysinit(int *argc, char ***argv) { #if RT_VER >= 80 static void set_pioinfo_extra(void); _CrtSetReportMode(_CRT_ASSERT, 0); _set_invalid_parameter_handler(invalid_parameter); _RTC_SetErrorFunc(rtc_error_handler); set_pioinfo_extra(); #endif get_version(); // // subvert cmd.exe's feeble attempt at command line parsing // *argc = rb_w32_cmdvector(GetCommandLine(), argv); // // Now set up the correct time stuff // tzset(); init_env(); init_func(); init_stdhandle(); InitializeCriticalSection(&select_mutex); atexit(exit_handler); // Initialize Winsock StartSockets(); } char * getlogin(void) { return (char *)NTLoginName; } #define MAXCHILDNUM 256 /* max num of child processes */ static struct ChildRecord { HANDLE hProcess; /* process handle */ rb_pid_t pid; /* process id */ } ChildRecord[MAXCHILDNUM]; #define FOREACH_CHILD(v) do { \ struct ChildRecord* v; \ for (v = ChildRecord; v < ChildRecord + sizeof(ChildRecord) / sizeof(ChildRecord[0]); ++v) #define END_FOREACH_CHILD } while (0) static struct ChildRecord * FindChildSlot(rb_pid_t pid) { FOREACH_CHILD(child) { if (child->pid == pid) { return child; } } END_FOREACH_CHILD; return NULL; } static struct ChildRecord * FindChildSlotByHandle(HANDLE h) { FOREACH_CHILD(child) { if (child->hProcess == h) { return child; } } END_FOREACH_CHILD; return NULL; } static void CloseChildHandle(struct ChildRecord *child) { HANDLE h = child->hProcess; child->hProcess = NULL; child->pid = 0; CloseHandle(h); } static struct ChildRecord * FindFreeChildSlot(void) { FOREACH_CHILD(child) { if (!child->pid) { child->pid = -1; /* lock the slot */ child->hProcess = NULL; return child; } } END_FOREACH_CHILD; return NULL; } /* ruby -lne 'BEGIN{$cmds = Hash.new(0); $mask = 1}' -e '$cmds[$_.downcase] |= $mask' -e '$mask <<= 1 if ARGF.eof' -e 'END{$cmds.sort.each{|n,f|puts " \"\\#{f.to_s(8)}\" #{n.dump} + 1,"}}' 98cmd ntcmd */ static const char *const szInternalCmds[] = { "\2" "assoc" + 1, "\3" "break" + 1, "\3" "call" + 1, "\3" "cd" + 1, "\1" "chcp" + 1, "\3" "chdir" + 1, "\3" "cls" + 1, "\2" "color" + 1, "\3" "copy" + 1, "\1" "ctty" + 1, "\3" "date" + 1, "\3" "del" + 1, "\3" "dir" + 1, "\3" "echo" + 1, "\2" "endlocal" + 1, "\3" "erase" + 1, "\3" "exit" + 1, "\3" "for" + 1, "\2" "ftype" + 1, "\3" "goto" + 1, "\3" "if" + 1, "\1" "lfnfor" + 1, "\1" "lh" + 1, "\1" "lock" + 1, "\3" "md" + 1, "\3" "mkdir" + 1, "\2" "move" + 1, "\3" "path" + 1, "\3" "pause" + 1, "\2" "popd" + 1, "\3" "prompt" + 1, "\2" "pushd" + 1, "\3" "rd" + 1, "\3" "rem" + 1, "\3" "ren" + 1, "\3" "rename" + 1, "\3" "rmdir" + 1, "\3" "set" + 1, "\2" "setlocal" + 1, "\3" "shift" + 1, "\2" "start" + 1, "\3" "time" + 1, "\2" "title" + 1, "\1" "truename" + 1, "\3" "type" + 1, "\1" "unlock" + 1, "\3" "ver" + 1, "\3" "verify" + 1, "\3" "vol" + 1, }; static int internal_match(const void *key, const void *elem) { return strcmp(key, *(const char *const *)elem); } static int is_command_com(const char *interp) { int i = strlen(interp) - 11; if ((i == 0 || i > 0 && isdirsep(interp[i-1])) && strcasecmp(interp+i, "command.com") == 0) { return 1; } return 0; } static int internal_cmd_match(const char *cmdname, int nt); static int is_internal_cmd(const char *cmd, int nt) { char cmdname[9], *b = cmdname, c; do { if (!(c = *cmd++)) return 0; } while (isspace(c)); while (isalpha(c)) { *b++ = tolower(c); if (b == cmdname + sizeof(cmdname)) return 0; c = *cmd++; } if (c == '.') c = *cmd; switch (c) { case '<': case '>': case '|': return 1; case '\0': case ' ': case '\t': case '\n': break; default: return 0; } *b = 0; return internal_cmd_match(cmdname, nt); } static int internal_cmd_match(const char *cmdname, int nt) { char **nm; nm = bsearch(cmdname, szInternalCmds, sizeof(szInternalCmds) / sizeof(*szInternalCmds), sizeof(*szInternalCmds), internal_match); if (!nm || !(nm[0][-1] & (nt ? 2 : 1))) return 0; return 1; } SOCKET rb_w32_get_osfhandle(int fh) { return _get_osfhandle(fh); } static int argv_size(char *const *argv, BOOL escape) { const char *p; char *const *t; int len, n, bs, quote; for (t = argv, len = 0; *t; t++) { for (p = *t, n = quote = bs = 0; *p; ++p) { switch (*p) { case '\\': ++bs; break; case '<': case '>': case '|': case '^': bs = 0; if (escape && !quote) n++; break; case '"': n += bs + 1; bs = 0; quote = 1; break; case ' ': case '\t': quote = 1; default: bs = 0; p = CharNext(p) - 1; break; } } len += p - *t + n + 1; if (p - *t == 0 || quote) len += 2; } return len; } static char * join_argv(char *cmd, char *const *argv, BOOL escape) { const char *p, *s; char *q, *const *t; int n, bs, quote; for (t = argv, q = cmd; p = *t; t++) { quote = 0; s = p; if (!*p || strpbrk(p, " \t\"'")) { quote = 1; *q++ = '"'; } for (bs = 0; *p; ++p) { switch (*p) { case '\\': ++bs; break; case '"': memcpy(q, s, n = p - s); q += n; s = p; memset(q, '\\', ++bs); q += bs; bs = 0; break; case '<': case '>': case '|': case '^': if (escape && !quote) { memcpy(q, s, n = p - s); q += n; s = p; *q++ = '^'; break; } default: bs = 0; p = CharNext(p) - 1; break; } } memcpy(q, s, n = p - s); q += n; if (quote) *q++ = '"'; *q++ = ' '; } if (q > cmd) --q; *q = '\0'; return cmd; } #ifdef HAVE_SYS_PARAM_H # include #else # define MAXPATHLEN 512 #endif #define STRNDUPA(ptr, src, len) \ (((char *)memcpy(((ptr) = ALLOCA_N(char, (len) + 1)), (src), (len)))[len] = 0) static int check_spawn_mode(int mode) { switch (mode) { case P_NOWAIT: case P_OVERLAY: return 0; default: errno = EINVAL; return -1; } } static rb_pid_t child_result(struct ChildRecord *child, int mode) { DWORD exitcode; if (!child) { return -1; } switch (mode) { case P_NOWAIT: return child->pid; case P_OVERLAY: WaitForSingleObject(child->hProcess, INFINITE); GetExitCodeProcess(child->hProcess, &exitcode); CloseChildHandle(child); _exit(exitcode); default: return -1; /* not reached */ } } static struct ChildRecord * CreateChild(const char *cmd, const char *prog, SECURITY_ATTRIBUTES *psa, HANDLE hInput, HANDLE hOutput, HANDLE hError) { BOOL fRet; DWORD dwCreationFlags; STARTUPINFO aStartupInfo; PROCESS_INFORMATION aProcessInformation; SECURITY_ATTRIBUTES sa; struct ChildRecord *child; if (!cmd && !prog) { errno = EFAULT; return NULL; } child = FindFreeChildSlot(); if (!child) { errno = EAGAIN; return NULL; } if (!psa) { sa.nLength = sizeof (SECURITY_ATTRIBUTES); sa.lpSecurityDescriptor = NULL; sa.bInheritHandle = TRUE; psa = &sa; } memset(&aStartupInfo, 0, sizeof (STARTUPINFO)); memset(&aProcessInformation, 0, sizeof (PROCESS_INFORMATION)); aStartupInfo.cb = sizeof (STARTUPINFO); aStartupInfo.dwFlags = STARTF_USESTDHANDLES; if (hInput) { aStartupInfo.hStdInput = hInput; } else { aStartupInfo.hStdInput = GetStdHandle(STD_INPUT_HANDLE); } if (hOutput) { aStartupInfo.hStdOutput = hOutput; } else { aStartupInfo.hStdOutput = GetStdHandle(STD_OUTPUT_HANDLE); } if (hError) { aStartupInfo.hStdError = hError; } else { aStartupInfo.hStdError = GetStdHandle(STD_ERROR_HANDLE); } dwCreationFlags = (NORMAL_PRIORITY_CLASS); RUBY_CRITICAL({ fRet = CreateProcess(prog, (char *)cmd, psa, psa, psa->bInheritHandle, dwCreationFlags, NULL, NULL, &aStartupInfo, &aProcessInformation); errno = map_errno(GetLastError()); }); if (!fRet) { child->pid = 0; /* release the slot */ return NULL; } CloseHandle(aProcessInformation.hThread); child->hProcess = aProcessInformation.hProcess; child->pid = (rb_pid_t)aProcessInformation.dwProcessId; if (!IsWinNT()) { /* On Win9x, make pid positive similarly to cygwin and perl */ child->pid = -child->pid; } return child; } static int is_batch(const char *cmd) { int len = strlen(cmd); if (len <= 4) return 0; cmd += len - 4; if (*cmd++ != '.') return 0; if (strcasecmp(cmd, "bat") == 0) return 1; if (strcasecmp(cmd, "cmd") == 0) return 1; return 0; } rb_pid_t rb_w32_spawn(int mode, const char *cmd, const char *prog) { char fbuf[MAXPATHLEN]; char *p = NULL; const char *shell = NULL; if (check_spawn_mode(mode)) return -1; if (prog) { if (!(p = dln_find_exe_r(prog, NULL, fbuf, sizeof(fbuf)))) { shell = prog; } else { shell = p; translate_char(p, '/', '\\'); } } else { int redir = -1; int nt; while (ISSPACE(*cmd)) cmd++; if ((shell = getenv("RUBYSHELL")) && (redir = has_redirection(cmd))) { char *tmp = ALLOCA_N(char, strlen(shell) + strlen(cmd) + sizeof(" -c ") + 2); sprintf(tmp, "%s -c \"%s\"", shell, cmd); cmd = tmp; } else if ((shell = getenv("COMSPEC")) && (nt = !is_command_com(shell), (redir < 0 ? has_redirection(cmd) : redir) || is_internal_cmd(cmd, nt))) { char *tmp = ALLOCA_N(char, strlen(shell) + strlen(cmd) + sizeof(" /c ") + (nt ? 2 : 0)); sprintf(tmp, nt ? "%s /c \"%s\"" : "%s /c %s", shell, cmd); cmd = tmp; } else { int len = 0, quote = (*cmd == '"') ? '"' : (*cmd == '\'') ? '\'' : 0; for (prog = cmd + !!quote;; prog = CharNext(prog)) { if (!*prog) { len = prog - cmd; shell = cmd; break; } if ((unsigned char)*prog == quote) { len = prog++ - cmd - 1; STRNDUPA(p, cmd + 1, len); shell = p; break; } if (quote) continue; if (ISSPACE(*prog) || strchr("<>|*?\"", *prog)) { len = prog - cmd; STRNDUPA(p, cmd, len); shell = p; break; } } shell = dln_find_exe_r(shell, NULL, fbuf, sizeof(fbuf)); if (!shell) { shell = p ? p : cmd; } else { len = strlen(shell); if (strchr(shell, ' ')) quote = -1; if (shell == fbuf) { p = fbuf; } else if (shell != p && strchr(shell, '/')) { STRNDUPA(p, shell, len); shell = p; } if (p) translate_char(p, '/', '\\'); if (is_batch(shell)) { int alen = strlen(prog); cmd = p = ALLOCA_N(char, len + alen + (quote ? 2 : 0) + 1); if (quote) *p++ = '"'; memcpy(p, shell, len); p += len; if (quote) *p++ = '"'; memcpy(p, prog, alen + 1); shell = 0; } } } } return child_result(CreateChild(cmd, shell, NULL, NULL, NULL, NULL), mode); } rb_pid_t rb_w32_aspawn(int mode, const char *prog, char *const *argv) { int c_switch = 0; size_t len; BOOL ntcmd = FALSE, tmpnt; const char *shell; char *cmd, fbuf[MAXPATHLEN]; if (check_spawn_mode(mode)) return -1; if (!prog) prog = argv[0]; if ((shell = getenv("COMSPEC")) && internal_cmd_match(prog, tmpnt = !is_command_com(shell))) { ntcmd = tmpnt; prog = shell; c_switch = 1; } else if ((cmd = dln_find_exe_r(prog, NULL, fbuf, sizeof(fbuf)))) { if (cmd == prog) strlcpy(cmd = fbuf, prog, sizeof(fbuf)); translate_char(cmd, '/', '\\'); prog = cmd; } else if (strchr(prog, '/')) { len = strlen(prog); if (len < sizeof(fbuf)) strlcpy(cmd = fbuf, prog, sizeof(fbuf)); else STRNDUPA(cmd, prog, len); translate_char(cmd, '/', '\\'); prog = cmd; } if (c_switch || is_batch(prog)) { char *progs[2]; progs[0] = (char *)prog; progs[1] = NULL; len = argv_size(progs, ntcmd); if (c_switch) len += 3; else ++argv; if (argv[0]) len += argv_size(argv, ntcmd); cmd = ALLOCA_N(char, len); join_argv(cmd, progs, ntcmd); if (c_switch) strlcat(cmd, " /c", len); if (argv[0]) join_argv(cmd + strlcat(cmd, " ", len), argv, ntcmd); prog = c_switch ? shell : 0; } else { len = argv_size(argv, FALSE); cmd = ALLOCA_N(char, len); join_argv(cmd, argv, FALSE); } return child_result(CreateChild(cmd, prog, NULL, NULL, NULL, NULL), mode); } typedef struct _NtCmdLineElement { struct _NtCmdLineElement *next; char *str; int len; int flags; } NtCmdLineElement; // // Possible values for flags // #define NTGLOB 0x1 // element contains a wildcard #define NTMALLOC 0x2 // string in element was malloc'ed #define NTSTRING 0x4 // element contains a quoted string static int insert(const char *path, VALUE vinfo, void *enc) { NtCmdLineElement *tmpcurr; NtCmdLineElement ***tail = (NtCmdLineElement ***)vinfo; tmpcurr = (NtCmdLineElement *)malloc(sizeof(NtCmdLineElement)); if (!tmpcurr) return -1; MEMZERO(tmpcurr, NtCmdLineElement, 1); tmpcurr->len = strlen(path); tmpcurr->str = strdup(path); if (!tmpcurr->str) return -1; tmpcurr->flags |= NTMALLOC; **tail = tmpcurr; *tail = &tmpcurr->next; return 0; } static NtCmdLineElement ** cmdglob(NtCmdLineElement *patt, NtCmdLineElement **tail) { char buffer[MAXPATHLEN], *buf = buffer; char *p; NtCmdLineElement **last = tail; int status; if (patt->len >= MAXPATHLEN) if (!(buf = malloc(patt->len + 1))) return 0; strlcpy(buf, patt->str, patt->len + 1); buf[patt->len] = '\0'; for (p = buf; *p; p = CharNext(p)) if (*p == '\\') *p = '/'; status = ruby_brace_glob(buf, 0, insert, (VALUE)&tail); if (buf != buffer) free(buf); if (status || last == tail) return 0; if (patt->flags & NTMALLOC) free(patt->str); free(patt); return tail; } // // Check a command string to determine if it has I/O redirection // characters that require it to be executed by a command interpreter // static int has_redirection(const char *cmd) { char quote = '\0'; const char *ptr; // // Scan the string, looking for redirection characters (< or >), pipe // character (|) or newline (\n) that are not in a quoted string // for (ptr = cmd; *ptr;) { switch (*ptr) { case '\'': case '\"': if (!quote) quote = *ptr; else if (quote == *ptr) quote = '\0'; ptr++; break; case '>': case '<': case '|': case '\n': if (!quote) return TRUE; ptr++; break; case '%': if (*++ptr != '_' && !ISALPHA(*ptr)) break; while (*++ptr == '_' || ISALNUM(*ptr)); if (*ptr++ == '%') return TRUE; break; case '\\': ptr++; default: ptr = CharNext(ptr); break; } } return FALSE; } static inline char * skipspace(char *ptr) { while (ISSPACE(*ptr)) ptr++; return ptr; } int rb_w32_cmdvector(const char *cmd, char ***vec) { int globbing, len; int elements, strsz, done; int slashes, escape; char *ptr, *base, *buffer, *cmdline; char **vptr; char quote; NtCmdLineElement *curr, **tail; NtCmdLineElement *cmdhead = NULL, **cmdtail = &cmdhead; // // just return if we don't have a command line // while (ISSPACE(*cmd)) cmd++; if (!*cmd) { *vec = NULL; return 0; } ptr = cmdline = strdup(cmd); // // Ok, parse the command line, building a list of CmdLineElements. // When we've finished, and it's an input command (meaning that it's // the processes argv), we'll do globing and then build the argument // vector. // The outer loop does one interation for each element seen. // The inner loop does one interation for each character in the element. // while (*(ptr = skipspace(ptr))) { base = ptr; quote = slashes = globbing = escape = 0; for (done = 0; !done && *ptr; ) { // // Switch on the current character. We only care about the // white-space characters, the wild-card characters, and the // quote characters. // switch (*ptr) { case '\\': if (quote != '\'') slashes++; break; case ' ': case '\t': case '\n': // // if we're not in a string, then we're finished with this // element // if (!quote) { *ptr = 0; done = 1; } break; case '*': case '?': case '[': case '{': // // record the fact that this element has a wildcard character // N.B. Don't glob if inside a single quoted string // if (quote != '\'') globbing++; slashes = 0; break; case '\'': case '\"': // // if we're already in a string, see if this is the // terminating close-quote. If it is, we're finished with // the string, but not neccessarily with the element. // If we're not already in a string, start one. // if (!(slashes & 1)) { if (!quote) quote = *ptr; else if (quote == *ptr) { if (quote == '"' && quote == ptr[1]) ptr++; quote = '\0'; } } escape++; slashes = 0; break; default: ptr = CharNext(ptr); slashes = 0; continue; } ptr++; } // // when we get here, we've got a pair of pointers to the element, // base and ptr. Base points to the start of the element while ptr // points to the character following the element. // len = ptr - base; if (done) --len; // // if it's an input vector element and it's enclosed by quotes, // we can remove them. // if (escape) { char *p = base, c; slashes = quote = 0; while (p < base + len) { switch (c = *p) { case '\\': p++; if (quote != '\'') slashes++; break; case '\'': case '"': if (!(slashes & 1) && quote && quote != c) { p++; slashes = 0; break; } memcpy(p - ((slashes + 1) >> 1), p + (~slashes & 1), base + len - p); len -= ((slashes + 1) >> 1) + (~slashes & 1); p -= (slashes + 1) >> 1; if (!(slashes & 1)) { if (quote) { if (quote == '"' && quote == *p) p++; quote = '\0'; } else quote = c; } else p++; slashes = 0; break; default: p = CharNext(p); slashes = 0; break; } } } curr = (NtCmdLineElement *)calloc(sizeof(NtCmdLineElement), 1); if (!curr) goto do_nothing; curr->str = base; curr->len = len; if (globbing && (tail = cmdglob(curr, cmdtail))) { cmdtail = tail; } else { *cmdtail = curr; cmdtail = &curr->next; } } // // Almost done! // Count up the elements, then allocate space for a vector of pointers // (argv) and a string table for the elements. // for (elements = 0, strsz = 0, curr = cmdhead; curr; curr = curr->next) { elements++; strsz += (curr->len + 1); } len = (elements+1)*sizeof(char *) + strsz; buffer = (char *)malloc(len); if (!buffer) { do_nothing: while (curr = cmdhead) { cmdhead = curr->next; if (curr->flags & NTMALLOC) free(curr->str); free(curr); } free(cmdline); for (vptr = *vec; *vptr; ++vptr); return vptr - *vec; } // // make vptr point to the start of the buffer // and ptr point to the area we'll consider the string table. // // buffer (*vec) // | // V ^---------------------V // +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ // | | | .... | NULL | | ..... |\0 | | ..... |\0 |... // +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ // |- elements+1 -| ^ 1st element ^ 2nd element vptr = (char **) buffer; ptr = buffer + (elements+1) * sizeof(char *); while (curr = cmdhead) { strlcpy(ptr, curr->str, curr->len + 1); *vptr++ = ptr; ptr += curr->len + 1; cmdhead = curr->next; if (curr->flags & NTMALLOC) free(curr->str); free(curr); } *vptr = 0; *vec = (char **) buffer; free(cmdline); return elements; } // // UNIX compatible directory access functions for NT // #define PATHLEN 1024 // // The idea here is to read all the directory names into a string table // (separated by nulls) and when one of the other dir functions is called // return the pointer to the current file name. // #define GetBit(bits, i) ((bits)[(i) / CHAR_BIT] & (1 << (i) % CHAR_BIT)) #define SetBit(bits, i) ((bits)[(i) / CHAR_BIT] |= (1 << (i) % CHAR_BIT)) #define BitOfIsDir(n) ((n) * 2) #define BitOfIsRep(n) ((n) * 2 + 1) #define DIRENT_PER_CHAR (CHAR_BIT / 2) static HANDLE open_dir_handle(const char *filename, WIN32_FIND_DATAW *fd) { HANDLE fh; static const WCHAR wildcard[] = L"\\*"; UINT cp = AreFileApisANSI() ? CP_ACP : CP_OEMCP; WCHAR *scanname; WCHAR *p; int len; // // Create the search pattern // len = MultiByteToWideChar(cp, 0, filename, -1, NULL, 0); if (len <= 0) { errno = map_errno(GetLastError()); return INVALID_HANDLE_VALUE; } scanname = ALLOCA_N(WCHAR, len + sizeof(wildcard) / sizeof(WCHAR)); len = MultiByteToWideChar(cp, 0, filename, -1, scanname, len + 2); if (len <= 0) { errno = map_errno(GetLastError()); return INVALID_HANDLE_VALUE; } p = CharPrevW(scanname, scanname + len); if (*p == L'/' || *p == L'\\' || *p == L':') lstrcatW(scanname, wildcard + 1); else lstrcatW(scanname, wildcard); // // do the FindFirstFile call // fh = FindFirstFileW(scanname, fd); if (fh == INVALID_HANDLE_VALUE) { errno = map_errno(GetLastError()); } return fh; } static DIR * opendir_internal(HANDLE fh, WIN32_FIND_DATAW *fd) { DIR *p; long len; long idx; WCHAR *tmpW; char *tmp; if (fh == INVALID_HANDLE_VALUE) { return NULL; } // // Get us a DIR structure // p = calloc(sizeof(DIR), 1); if (p == NULL) return NULL; idx = 0; // // loop finding all the files that match the wildcard // (which should be all of them in this directory!). // the variable idx should point one past the null terminator // of the previous string found. // do { len = lstrlenW(fd->cFileName) + 1; // // bump the string table size by enough for the // new name and it's null terminator // tmpW = realloc(p->start, (idx + len) * sizeof(WCHAR)); if (!tmpW) { error: rb_w32_closedir(p); FindClose(fh); errno = ENOMEM; return NULL; } p->start = tmpW; memcpy(&p->start[idx], fd->cFileName, len * sizeof(WCHAR)); if (p->nfiles % DIRENT_PER_CHAR == 0) { tmp = realloc(p->bits, p->nfiles / DIRENT_PER_CHAR + 1); if (!tmp) goto error; p->bits = tmp; p->bits[p->nfiles / DIRENT_PER_CHAR] = 0; } if (fd->dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) SetBit(p->bits, BitOfIsDir(p->nfiles)); if (fd->dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) SetBit(p->bits, BitOfIsRep(p->nfiles)); p->nfiles++; idx += len; } while (FindNextFileW(fh, fd)); FindClose(fh); p->size = idx; p->curr = p->start; return p; } DIR * rb_w32_opendir(const char *filename) { struct stati64 sbuf; WIN32_FIND_DATAW fd; HANDLE fh; // // check to see if we've got a directory // if (rb_w32_stati64(filename, &sbuf) < 0) return NULL; if (!(sbuf.st_mode & S_IFDIR) && (!ISALPHA(filename[0]) || filename[1] != ':' || filename[2] != '\0' || ((1 << ((filename[0] & 0x5f) - 'A')) & GetLogicalDrives()) == 0)) { errno = ENOTDIR; return NULL; } fh = open_dir_handle(filename, &fd); return opendir_internal(fh, &fd); } // // Move to next entry // static void move_to_next_entry(DIR *dirp) { if (dirp->curr) { dirp->loc++; dirp->curr += lstrlenW(dirp->curr) + 1; if (dirp->curr >= (dirp->start + dirp->size)) { dirp->curr = NULL; } } } static char * win32_conv_from_wstr(const WCHAR *wstr, long *len) { UINT cp = AreFileApisANSI() ? CP_ACP : CP_OEMCP; char *ptr; *len = WideCharToMultiByte(cp, 0, wstr, -1, NULL, 0, NULL, NULL) - 1; if (!(ptr = malloc(*len + 1))) return 0; WideCharToMultiByte(cp, 0, wstr, -1, ptr, *len + 1, NULL, NULL); return ptr; } // // Readdir just returns the current string pointer and bumps the // string pointer to the next entry. // static BOOL win32_direct_conv(const WCHAR *file, struct direct *entry, rb_encoding *dummy) { if (!(entry->d_name = win32_conv_from_wstr(file, &entry->d_namlen))) return FALSE; return TRUE; } VALUE rb_w32_conv_from_wchar(const WCHAR *wstr, rb_encoding *enc) { static rb_encoding *utf16 = (rb_encoding *)-1; VALUE src; VALUE opthash; int ecflags; VALUE ecopts; if (utf16 == (rb_encoding *)-1) { utf16 = rb_enc_find("UTF-16LE"); if (utf16 == rb_ascii8bit_encoding()) utf16 = NULL; } if (!utf16) /* maybe miniruby */ return Qnil; src = rb_enc_str_new((char *)wstr, lstrlenW(wstr) * sizeof(WCHAR), utf16); opthash = rb_hash_new(); rb_hash_aset(opthash, ID2SYM(rb_intern("undef")), ID2SYM(rb_intern("replace"))); ecflags = rb_econv_prepare_opts(opthash, &ecopts); return rb_str_encode(src, rb_enc_from_encoding(enc), ecflags, ecopts); } char * rb_w32_conv_from_wstr(const WCHAR *wstr, long *lenp, rb_encoding *enc) { VALUE str = rb_w32_conv_from_wchar(wstr, enc); long len; char *ptr; if (NIL_P(str)) return win32_conv_from_wstr(wstr, lenp); *lenp = len = RSTRING_LEN(str); memcpy(ptr = malloc(len + 1), RSTRING_PTR(str), len); ptr[len] = '\0'; return ptr; } static BOOL ruby_direct_conv(const WCHAR *file, struct direct *entry, rb_encoding *enc) { if (!(entry->d_name = rb_w32_conv_from_wstr(file, &entry->d_namlen, enc))) return FALSE; return TRUE; } static struct direct * readdir_internal(DIR *dirp, BOOL (*conv)(const WCHAR *, struct direct *, rb_encoding *), rb_encoding *enc) { static int dummy = 0; if (dirp->curr) { // // first set up the structure to return // if (dirp->dirstr.d_name) free(dirp->dirstr.d_name); conv(dirp->curr, &dirp->dirstr, enc); // // Fake inode // dirp->dirstr.d_ino = dummy++; // // Attributes // dirp->dirstr.d_isdir = GetBit(dirp->bits, BitOfIsDir(dirp->loc)); dirp->dirstr.d_isrep = GetBit(dirp->bits, BitOfIsRep(dirp->loc)); // // Now set up for the next call to readdir // move_to_next_entry(dirp); return &(dirp->dirstr); } else return NULL; } struct direct * rb_w32_readdir(DIR *dirp) { return readdir_internal(dirp, win32_direct_conv, NULL); } struct direct * rb_w32_readdir_with_enc(DIR *dirp, rb_encoding *enc) { if (enc == rb_ascii8bit_encoding()) return readdir_internal(dirp, win32_direct_conv, NULL); else return readdir_internal(dirp, ruby_direct_conv, enc); } // // Telldir returns the current string pointer position // long rb_w32_telldir(DIR *dirp) { return dirp->loc; } // // Seekdir moves the string pointer to a previously saved position // (Saved by telldir). void rb_w32_seekdir(DIR *dirp, long loc) { if (dirp->loc > loc) rb_w32_rewinddir(dirp); while (dirp->curr && dirp->loc < loc) { move_to_next_entry(dirp); } } // // Rewinddir resets the string pointer to the start // void rb_w32_rewinddir(DIR *dirp) { dirp->curr = dirp->start; dirp->loc = 0; } // // This just free's the memory allocated by opendir // void rb_w32_closedir(DIR *dirp) { if (dirp) { if (dirp->dirstr.d_name) free(dirp->dirstr.d_name); if (dirp->start) free(dirp->start); if (dirp->bits) free(dirp->bits); free(dirp); } } #if (defined _MT || defined __MSVCRT__) && !defined __BORLANDC__ #define MSVCRT_THREADS #endif #ifdef MSVCRT_THREADS # define MTHREAD_ONLY(x) x # define STHREAD_ONLY(x) #elif defined(__BORLANDC__) # define MTHREAD_ONLY(x) # define STHREAD_ONLY(x) #else # define MTHREAD_ONLY(x) # define STHREAD_ONLY(x) x #endif typedef struct { intptr_t osfhnd; /* underlying OS file HANDLE */ char osfile; /* attributes of file (e.g., open in text mode?) */ char pipech; /* one char buffer for handles opened on pipes */ #ifdef MSVCRT_THREADS int lockinitflag; CRITICAL_SECTION lock; #endif #if RT_VER >= 80 char textmode; char pipech2[2]; #endif } ioinfo; #if !defined _CRTIMP || defined __MINGW32__ #undef _CRTIMP #define _CRTIMP __declspec(dllimport) #endif #if !defined(__BORLANDC__) EXTERN_C _CRTIMP ioinfo * __pioinfo[]; #define IOINFO_L2E 5 #define IOINFO_ARRAY_ELTS (1 << IOINFO_L2E) #define _pioinfo(i) ((ioinfo*)((char*)(__pioinfo[i >> IOINFO_L2E]) + (i & (IOINFO_ARRAY_ELTS - 1)) * (sizeof(ioinfo) + pioinfo_extra))) #define _osfhnd(i) (_pioinfo(i)->osfhnd) #define _osfile(i) (_pioinfo(i)->osfile) #define _pipech(i) (_pioinfo(i)->pipech) #if RT_VER >= 80 static size_t pioinfo_extra = 0; /* workaround for VC++8 SP1 */ static void set_pioinfo_extra(void) { int fd; fd = _open("NUL", O_RDONLY); for (pioinfo_extra = 0; pioinfo_extra <= 64; pioinfo_extra += sizeof(void *)) { if (_osfhnd(fd) == _get_osfhandle(fd)) { break; } } _close(fd); if (pioinfo_extra > 64) { /* not found, maybe something wrong... */ pioinfo_extra = 0; } } #else #define pioinfo_extra 0 #endif #define _set_osfhnd(fh, osfh) (void)(_osfhnd(fh) = osfh) #define _set_osflags(fh, flags) (_osfile(fh) = (flags)) #define FOPEN 0x01 /* file handle open */ #define FEOFLAG 0x02 /* end of file has been encountered */ #define FPIPE 0x08 /* file handle refers to a pipe */ #define FNOINHERIT 0x10 /* file handle opened O_NOINHERIT */ #define FAPPEND 0x20 /* file handle opened O_APPEND */ #define FDEV 0x40 /* file handle refers to device */ #define FTEXT 0x80 /* file handle is in text mode */ static int rb_w32_open_osfhandle(intptr_t osfhandle, int flags) { int fh; char fileflags; /* _osfile flags */ HANDLE hF; /* copy relevant flags from second parameter */ fileflags = FDEV; if (flags & O_APPEND) fileflags |= FAPPEND; if (flags & O_TEXT) fileflags |= FTEXT; if (flags & O_NOINHERIT) fileflags |= FNOINHERIT; /* attempt to allocate a C Runtime file handle */ hF = CreateFile("NUL", 0, 0, NULL, OPEN_ALWAYS, 0, NULL); fh = _open_osfhandle((long)hF, 0); CloseHandle(hF); if (fh == -1) { errno = EMFILE; /* too many open files */ _doserrno = 0L; /* not an OS error */ } else { MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fh)->lock))); /* the file is open. now, set the info in _osfhnd array */ _set_osfhnd(fh, osfhandle); fileflags |= FOPEN; /* mark as open */ _set_osflags(fh, fileflags); /* set osfile entry */ MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fh)->lock)); } return fh; /* return handle */ } static void init_stdhandle(void) { int nullfd = -1; int keep = 0; #define open_null(fd) \ (((nullfd < 0) ? \ (nullfd = open("NUL", O_RDWR|O_BINARY)) : 0), \ ((nullfd == (fd)) ? (keep = 1) : dup2(nullfd, fd)), \ (fd)) if (fileno(stdin) < 0) { stdin->_file = open_null(0); } else { setmode(fileno(stdin), O_BINARY); } if (fileno(stdout) < 0) { stdout->_file = open_null(1); } else { setmode(fileno(stdout), O_BINARY); } if (fileno(stderr) < 0) { stderr->_file = open_null(2); } else { setmode(fileno(stderr), O_BINARY); } if (nullfd >= 0 && !keep) close(nullfd); setvbuf(stderr, NULL, _IONBF, 0); } #else #define _set_osfhnd(fh, osfh) (void)((fh), (osfh)) #define _set_osflags(fh, flags) (void)((fh), (flags)) static void init_stdhandle(void) { } #endif #ifdef __BORLANDC__ static int rb_w32_open_osfhandle(intptr_t osfhandle, int flags) { int fd = _open_osfhandle(osfhandle, flags); if (fd == -1) { errno = EMFILE; /* too many open files */ _doserrno = 0L; /* not an OS error */ } return fd; } #endif #undef getsockopt static int is_socket(SOCKET sock) { if (st_lookup(socklist, (st_data_t)sock, NULL)) return TRUE; else return FALSE; } int rb_w32_is_socket(int fd) { return is_socket(TO_SOCKET(fd)); } // // Since the errors returned by the socket error function // WSAGetLastError() are not known by the library routine strerror // we have to roll our own. // #undef strerror char * rb_w32_strerror(int e) { static char buffer[512]; DWORD source = 0; char *p; #if defined __BORLANDC__ && defined ENOTEMPTY // _sys_errlist is broken switch (e) { case ENAMETOOLONG: return "Filename too long"; case ENOTEMPTY: return "Directory not empty"; } #endif if (e < 0 || e > sys_nerr) { if (e < 0) e = GetLastError(); if (FormatMessage(FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, &source, e, 0, buffer, sizeof(buffer), NULL) == 0) strlcpy(buffer, "Unknown Error", sizeof(buffer)); } else strlcpy(buffer, strerror(e), sizeof(buffer)); p = buffer; while ((p = strpbrk(p, "\r\n")) != NULL) { memmove(p, p + 1, strlen(p)); } return buffer; } // // various stubs // // Ownership // // Just pretend that everyone is a superuser. NT will let us know if // we don't really have permission to do something. // #define ROOT_UID 0 #define ROOT_GID 0 rb_uid_t getuid(void) { return ROOT_UID; } rb_uid_t geteuid(void) { return ROOT_UID; } rb_gid_t getgid(void) { return ROOT_GID; } rb_gid_t getegid(void) { return ROOT_GID; } int setuid(rb_uid_t uid) { return (uid == ROOT_UID ? 0 : -1); } int setgid(rb_gid_t gid) { return (gid == ROOT_GID ? 0 : -1); } // // File system stuff // int ioctl(int i, int u, ...) { errno = EINVAL; return -1; } #undef FD_SET void rb_w32_fdset(int fd, fd_set *set) { unsigned int i; SOCKET s = TO_SOCKET(fd); for (i = 0; i < set->fd_count; i++) { if (set->fd_array[i] == s) { return; } } if (i == set->fd_count) { if (set->fd_count < FD_SETSIZE) { set->fd_array[i] = s; set->fd_count++; } } } #undef FD_CLR void rb_w32_fdclr(int fd, fd_set *set) { unsigned int i; SOCKET s = TO_SOCKET(fd); for (i = 0; i < set->fd_count; i++) { if (set->fd_array[i] == s) { memmove(&set->fd_array[i], &set->fd_array[i+1], sizeof(set->fd_array[0]) * (--set->fd_count - i)); break; } } } #undef FD_ISSET int rb_w32_fdisset(int fd, fd_set *set) { int ret; SOCKET s = TO_SOCKET(fd); if (s == (SOCKET)INVALID_HANDLE_VALUE) return 0; RUBY_CRITICAL(ret = __WSAFDIsSet(s, set)); return ret; } // // Networking trampolines // These are used to avoid socket startup/shutdown overhead in case // the socket routines aren't used. // #undef select static int extract_fd(rb_fdset_t *dst, fd_set *src, int (*func)(SOCKET)) { unsigned int s = 0; if (!src || !dst) return 0; while (s < src->fd_count) { SOCKET fd = src->fd_array[s]; if (!func || (*func)(fd)) { /* move it to dst */ unsigned int d; for (d = 0; d < dst->fdset->fd_count; d++) { if (dst->fdset->fd_array[d] == fd) break; } if (d == dst->fdset->fd_count) { if ((int)dst->fdset->fd_count >= dst->capa) { dst->capa = (dst->fdset->fd_count / FD_SETSIZE + 1) * FD_SETSIZE; dst->fdset = xrealloc(dst->fdset, sizeof(unsigned int) + sizeof(SOCKET) * dst->capa); } dst->fdset->fd_array[dst->fdset->fd_count++] = fd; } memmove( &src->fd_array[s], &src->fd_array[s+1], sizeof(src->fd_array[0]) * (--src->fd_count - s)); } else s++; } return dst->fdset->fd_count; } static int copy_fd(fd_set *dst, fd_set *src) { unsigned int s; if (!src || !dst) return 0; for (s = 0; s < src->fd_count; ++s) { SOCKET fd = src->fd_array[s]; unsigned int d; for (d = 0; d < dst->fd_count; ++d) { if (dst->fd_array[d] == fd) break; } if (d == dst->fd_count && d < FD_SETSIZE) { dst->fd_array[dst->fd_count++] = fd; } } return dst->fd_count; } static int is_not_socket(SOCKET sock) { return !is_socket(sock); } static int is_pipe(SOCKET sock) /* DONT call this for SOCKET! it clains it is PIPE. */ { int ret; RUBY_CRITICAL({ ret = (GetFileType((HANDLE)sock) == FILE_TYPE_PIPE); }); return ret; } static int is_readable_pipe(SOCKET sock) /* call this for pipe only */ { int ret; DWORD n = 0; RUBY_CRITICAL( if (PeekNamedPipe((HANDLE)sock, NULL, 0, NULL, &n, NULL)) { ret = (n > 0); } else { ret = (GetLastError() == ERROR_BROKEN_PIPE); /* pipe was closed */ } ); return ret; } static int is_console(SOCKET sock) /* DONT call this for SOCKET! */ { int ret; DWORD n = 0; INPUT_RECORD ir; RUBY_CRITICAL( ret = (PeekConsoleInput((HANDLE)sock, &ir, 1, &n)) ); return ret; } static int is_readable_console(SOCKET sock) /* call this for console only */ { int ret = 0; DWORD n = 0; INPUT_RECORD ir; RUBY_CRITICAL( if (PeekConsoleInput((HANDLE)sock, &ir, 1, &n) && n > 0) { if (ir.EventType == KEY_EVENT && ir.Event.KeyEvent.bKeyDown && ir.Event.KeyEvent.uChar.AsciiChar) { ret = 1; } else { ReadConsoleInput((HANDLE)sock, &ir, 1, &n); } } ); return ret; } static int do_select(int nfds, fd_set *rd, fd_set *wr, fd_set *ex, struct timeval *timeout) { int r = 0; if (nfds == 0) { if (timeout) rb_w32_sleep(timeout->tv_sec * 1000 + timeout->tv_usec / 1000); else rb_w32_sleep(INFINITE); } else { RUBY_CRITICAL( EnterCriticalSection(&select_mutex); r = select(nfds, rd, wr, ex, timeout); LeaveCriticalSection(&select_mutex); if (r == SOCKET_ERROR) { errno = map_errno(WSAGetLastError()); r = -1; } ); } return r; } static inline int subtract(struct timeval *rest, const struct timeval *wait) { if (rest->tv_sec < wait->tv_sec) { return 0; } while (rest->tv_usec < wait->tv_usec) { if (rest->tv_sec <= wait->tv_sec) { return 0; } rest->tv_sec -= 1; rest->tv_usec += 1000 * 1000; } rest->tv_sec -= wait->tv_sec; rest->tv_usec -= wait->tv_usec; return 1; } static inline int compare(const struct timeval *t1, const struct timeval *t2) { if (t1->tv_sec < t2->tv_sec) return -1; if (t1->tv_sec > t2->tv_sec) return 1; if (t1->tv_usec < t2->tv_usec) return -1; if (t1->tv_usec > t2->tv_usec) return 1; return 0; } #undef Sleep int WSAAPI rb_w32_select(int nfds, fd_set *rd, fd_set *wr, fd_set *ex, struct timeval *timeout) { int r; rb_fdset_t pipe_rd; rb_fdset_t cons_rd; rb_fdset_t else_rd; rb_fdset_t else_wr; rb_fdset_t except; int nonsock = 0; struct timeval limit = {0, 0}; if (nfds < 0 || (timeout && (timeout->tv_sec < 0 || timeout->tv_usec < 0))) { errno = EINVAL; return -1; } if (timeout) { if (timeout->tv_sec < 0 || timeout->tv_usec < 0 || timeout->tv_usec >= 1000000) { errno = EINVAL; return -1; } gettimeofday(&limit, NULL); limit.tv_sec += timeout->tv_sec; limit.tv_usec += timeout->tv_usec; if (limit.tv_usec >= 1000000) { limit.tv_usec -= 1000000; limit.tv_sec++; } } if (!NtSocketsInitialized) { StartSockets(); } // assume else_{rd,wr} (other than socket, pipe reader, console reader) // are always readable/writable. but this implementation still has // problem. if pipe's buffer is full, writing to pipe will block // until some data is read from pipe. but ruby is single threaded system, // so whole system will be blocked forever. rb_fd_init(&else_rd); nonsock += extract_fd(&else_rd, rd, is_not_socket); rb_fd_init(&pipe_rd); extract_fd(&pipe_rd, else_rd.fdset, is_pipe); // should not call is_pipe for socket rb_fd_init(&cons_rd); extract_fd(&cons_rd, else_rd.fdset, is_console); // ditto rb_fd_init(&else_wr); nonsock += extract_fd(&else_wr, wr, is_not_socket); rb_fd_init(&except); extract_fd(&except, ex, is_not_socket); // drop only r = 0; if (rd && (int)rd->fd_count > r) r = (int)rd->fd_count; if (wr && (int)wr->fd_count > r) r = (int)wr->fd_count; if (ex && (int)ex->fd_count > r) r = (int)ex->fd_count; if (nfds > r) nfds = r; { struct timeval rest; struct timeval wait; struct timeval zero; wait.tv_sec = 0; wait.tv_usec = 10 * 1000; // 10ms zero.tv_sec = 0; zero.tv_usec = 0; // 0ms for (;;) { if (nonsock) { // modifying {else,pipe,cons}_rd is safe because // if they are modified, function returns immediately. extract_fd(&else_rd, pipe_rd.fdset, is_readable_pipe); extract_fd(&else_rd, cons_rd.fdset, is_readable_console); } if (else_rd.fdset->fd_count || else_wr.fdset->fd_count) { r = do_select(nfds, rd, wr, ex, &zero); // polling if (r < 0) break; // XXX: should I ignore error and return signaled handles? r = copy_fd(rd, else_rd.fdset); r += copy_fd(wr, else_wr.fdset); if (ex) r += ex->fd_count; break; } else { struct timeval *dowait = &wait; fd_set orig_rd; fd_set orig_wr; fd_set orig_ex; if (rd) orig_rd = *rd; if (wr) orig_wr = *wr; if (ex) orig_ex = *ex; r = do_select(nfds, rd, wr, ex, &zero); // polling if (r != 0) break; // signaled or error if (rd) *rd = orig_rd; if (wr) *wr = orig_wr; if (ex) *ex = orig_ex; if (timeout) { struct timeval now; gettimeofday(&now, NULL); rest = limit; if (!subtract(&rest, &now)) break; if (compare(&rest, &wait) < 0) dowait = &rest; } Sleep(dowait->tv_sec * 1000 + dowait->tv_usec / 1000); } } } rb_fd_term(&except); rb_fd_term(&else_wr); rb_fd_term(&cons_rd); rb_fd_term(&pipe_rd); rb_fd_term(&else_rd); return r; } #undef accept int WSAAPI rb_w32_accept(int s, struct sockaddr *addr, int *addrlen) { SOCKET r; int fd; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ HANDLE h = CreateFile("NUL", 0, 0, NULL, OPEN_ALWAYS, 0, NULL); fd = rb_w32_open_osfhandle((intptr_t)h, O_RDWR|O_BINARY|O_NOINHERIT); if (fd != -1) { r = accept(TO_SOCKET(s), addr, addrlen); if (r != INVALID_SOCKET) { MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fd)->lock))); _set_osfhnd(fd, r); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); CloseHandle(h); st_insert(socklist, (st_data_t)r, (st_data_t)0); } else { errno = map_errno(WSAGetLastError()); close(fd); fd = -1; } } else CloseHandle(h); }); return fd; } #undef bind int WSAAPI rb_w32_bind(int s, const struct sockaddr *addr, int addrlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = bind(TO_SOCKET(s), addr, addrlen); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef connect int WSAAPI rb_w32_connect(int s, const struct sockaddr *addr, int addrlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = connect(TO_SOCKET(s), addr, addrlen); if (r == SOCKET_ERROR) { int err = WSAGetLastError(); if (err != WSAEWOULDBLOCK) errno = map_errno(err); else errno = EINPROGRESS; } }); return r; } #undef getpeername int WSAAPI rb_w32_getpeername(int s, struct sockaddr *addr, int *addrlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getpeername(TO_SOCKET(s), addr, addrlen); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef getsockname int WSAAPI rb_w32_getsockname(int s, struct sockaddr *addr, int *addrlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getsockname(TO_SOCKET(s), addr, addrlen); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } int WSAAPI rb_w32_getsockopt(int s, int level, int optname, char *optval, int *optlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getsockopt(TO_SOCKET(s), level, optname, optval, optlen); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef ioctlsocket int WSAAPI rb_w32_ioctlsocket(int s, long cmd, u_long *argp) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = ioctlsocket(TO_SOCKET(s), cmd, argp); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef listen int WSAAPI rb_w32_listen(int s, int backlog) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = listen(TO_SOCKET(s), backlog); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef recv #undef recvfrom #undef send #undef sendto static int overlapped_socket_io(BOOL input, int fd, char *buf, int len, int flags, struct sockaddr *addr, int *addrlen) { int r; int ret; int mode; st_data_t data; DWORD flg; WSAOVERLAPPED wol; WSABUF wbuf; int err; SOCKET s; if (!NtSocketsInitialized) StartSockets(); s = TO_SOCKET(fd); st_lookup(socklist, (st_data_t)s, &data); mode = (int)data; if (!cancel_io || (mode & O_NONBLOCK)) { RUBY_CRITICAL({ if (input) { if (addr && addrlen) r = recvfrom(s, buf, len, flags, addr, addrlen); else r = recv(s, buf, len, flags); } else { if (addr && addrlen) r = sendto(s, buf, len, flags, addr, *addrlen); else r = send(s, buf, len, flags); } if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); } else { DWORD size; wbuf.len = len; wbuf.buf = buf; memset(&wol, 0, sizeof(wol)); RUBY_CRITICAL({ wol.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (input) { flg = flags; if (addr && addrlen) ret = WSARecvFrom(s, &wbuf, 1, &size, &flg, addr, addrlen, &wol, NULL); else ret = WSARecv(s, &wbuf, 1, &size, &flg, &wol, NULL); } else { if (addr && addrlen) ret = WSASendTo(s, &wbuf, 1, &size, flags, addr, *addrlen, &wol, NULL); else ret = WSASend(s, &wbuf, 1, &size, flags, &wol, NULL); } }); if (ret != SOCKET_ERROR) { r = size; } else if ((err = WSAGetLastError()) == WSA_IO_PENDING) { switch (rb_w32_wait_events_blocking(&wol.hEvent, 1, INFINITE)) { case WAIT_OBJECT_0: RUBY_CRITICAL( ret = WSAGetOverlappedResult(s, &wol, &size, TRUE, &flg) ); if (ret) { r = size; break; } /* thru */ default: errno = map_errno(WSAGetLastError()); /* thru */ case WAIT_OBJECT_0 + 1: /* interrupted */ r = -1; cancel_io((HANDLE)s); break; } } else { errno = map_errno(err); r = -1; } CloseHandle(wol.hEvent); } return r; } int WSAAPI rb_w32_recv(int fd, char *buf, int len, int flags) { return overlapped_socket_io(TRUE, fd, buf, len, flags, NULL, NULL); } int WSAAPI rb_w32_recvfrom(int fd, char *buf, int len, int flags, struct sockaddr *from, int *fromlen) { return overlapped_socket_io(TRUE, fd, buf, len, flags, from, fromlen); } int WSAAPI rb_w32_send(int fd, const char *buf, int len, int flags) { return overlapped_socket_io(FALSE, fd, (char *)buf, len, flags, NULL, NULL); } int WSAAPI rb_w32_sendto(int fd, const char *buf, int len, int flags, const struct sockaddr *to, int tolen) { return overlapped_socket_io(FALSE, fd, (char *)buf, len, flags, (struct sockaddr *)to, &tolen); } #if !defined(MSG_TRUNC) && !defined(__MINGW32__) typedef struct { SOCKADDR *name; int namelen; WSABUF *lpBuffers; DWORD dwBufferCount; WSABUF Control; DWORD dwFlags; } WSAMSG; #endif #ifndef WSAID_WSARECVMSG #define WSAID_WSARECVMSG {0xf689d7c8,0x6f1f,0x436b,{0x8a,0x53,0xe5,0x4f,0xe3,0x51,0xc3,0x22}} #endif #ifndef WSAID_WSASENDMSG #define WSAID_WSASENDMSG {0xa441e712,0x754f,0x43ca,{0x84,0xa7,0x0d,0xee,0x44,0xcf,0x60,0x6d}} #endif #define msghdr_to_wsamsg(msg, wsamsg) \ do { \ int i; \ (wsamsg)->name = (msg)->msg_name; \ (wsamsg)->namelen = (msg)->msg_namelen; \ (wsamsg)->lpBuffers = ALLOCA_N(WSABUF, (msg)->msg_iovlen); \ (wsamsg)->dwBufferCount = (msg)->msg_iovlen; \ for (i = 0; i < (msg)->msg_iovlen; ++i) { \ (wsamsg)->lpBuffers[i].buf = (msg)->msg_iov[i].iov_base; \ (wsamsg)->lpBuffers[i].len = (msg)->msg_iov[i].iov_len; \ } \ (wsamsg)->Control.buf = (msg)->msg_control; \ (wsamsg)->Control.len = (msg)->msg_controllen; \ (wsamsg)->dwFlags = (msg)->msg_flags; \ } while (0) int recvmsg(int fd, struct msghdr *msg, int flags) { typedef int (WSAAPI *WSARecvMsg_t)(SOCKET, WSAMSG *, DWORD *, WSAOVERLAPPED *, LPWSAOVERLAPPED_COMPLETION_ROUTINE); static WSARecvMsg_t pWSARecvMsg = NULL; WSAMSG wsamsg; SOCKET s; st_data_t data; int mode; DWORD len; int ret; if (!NtSocketsInitialized) StartSockets(); s = TO_SOCKET(fd); if (!pWSARecvMsg) { static GUID guid = WSAID_WSARECVMSG; DWORD dmy; WSAIoctl(s, SIO_GET_EXTENSION_FUNCTION_POINTER, &guid, sizeof(guid), &pWSARecvMsg, sizeof(pWSARecvMsg), &dmy, NULL, NULL); if (!pWSARecvMsg) { errno = ENOSYS; return -1; } } msghdr_to_wsamsg(msg, &wsamsg); wsamsg.dwFlags |= flags; st_lookup(socklist, (st_data_t)s, &data); mode = (int)data; if (!cancel_io || (mode & O_NONBLOCK)) { RUBY_CRITICAL({ if ((ret = pWSARecvMsg(s, &wsamsg, &len, NULL, NULL)) == SOCKET_ERROR) { errno = map_errno(WSAGetLastError()); len = -1; } }); } else { DWORD size; int err; WSAOVERLAPPED wol; memset(&wol, 0, sizeof(wol)); RUBY_CRITICAL({ wol.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); ret = pWSARecvMsg(s, &wsamsg, &len, &wol, NULL); }); if (ret != SOCKET_ERROR) { /* nothing to do */ } else if ((err = WSAGetLastError()) == WSA_IO_PENDING) { DWORD flg; switch (rb_w32_wait_events_blocking(&wol.hEvent, 1, INFINITE)) { case WAIT_OBJECT_0: RUBY_CRITICAL( ret = WSAGetOverlappedResult(s, &wol, &size, TRUE, &flg) ); if (ret) { len = size; break; } /* thru */ default: errno = map_errno(WSAGetLastError()); /* thru */ case WAIT_OBJECT_0 + 1: /* interrupted */ len = -1; cancel_io((HANDLE)s); break; } } else { errno = map_errno(err); len = -1; } CloseHandle(wol.hEvent); } if (ret == SOCKET_ERROR) return -1; /* WSAMSG to msghdr */ msg->msg_name = wsamsg.name; msg->msg_namelen = wsamsg.namelen; msg->msg_flags = wsamsg.dwFlags; return len; } int sendmsg(int fd, const struct msghdr *msg, int flags) { typedef int (WSAAPI *WSASendMsg_t)(SOCKET, const WSAMSG *, DWORD, DWORD *, WSAOVERLAPPED *, LPWSAOVERLAPPED_COMPLETION_ROUTINE); static WSASendMsg_t pWSASendMsg = NULL; WSAMSG wsamsg; SOCKET s; st_data_t data; int mode; DWORD len; int ret; if (!NtSocketsInitialized) StartSockets(); s = TO_SOCKET(fd); if (!pWSASendMsg) { static GUID guid = WSAID_WSASENDMSG; DWORD dmy; WSAIoctl(s, SIO_GET_EXTENSION_FUNCTION_POINTER, &guid, sizeof(guid), &pWSASendMsg, sizeof(pWSASendMsg), &dmy, NULL, NULL); if (!pWSASendMsg) { errno = ENOSYS; return -1; } } msghdr_to_wsamsg(msg, &wsamsg); st_lookup(socklist, (st_data_t)s, &data); mode = (int)data; if (!cancel_io || (mode & O_NONBLOCK)) { RUBY_CRITICAL({ if ((ret = pWSASendMsg(s, &wsamsg, flags, &len, NULL, NULL)) == SOCKET_ERROR) { errno = map_errno(WSAGetLastError()); len = -1; } }); } else { DWORD size; int err; WSAOVERLAPPED wol; memset(&wol, 0, sizeof(wol)); RUBY_CRITICAL({ wol.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); ret = pWSASendMsg(s, &wsamsg, flags, &len, &wol, NULL); }); if (ret != SOCKET_ERROR) { /* nothing to do */ } else if ((err = WSAGetLastError()) == WSA_IO_PENDING) { DWORD flg; switch (rb_w32_wait_events_blocking(&wol.hEvent, 1, INFINITE)) { case WAIT_OBJECT_0: RUBY_CRITICAL( ret = WSAGetOverlappedResult(s, &wol, &size, TRUE, &flg) ); if (ret) { len = size; break; } /* thru */ default: errno = map_errno(WSAGetLastError()); /* thru */ case WAIT_OBJECT_0 + 1: /* interrupted */ len = -1; cancel_io((HANDLE)s); break; } } else { errno = map_errno(err); len = -1; } CloseHandle(wol.hEvent); } return len; } #undef setsockopt int WSAAPI rb_w32_setsockopt(int s, int level, int optname, const char *optval, int optlen) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = setsockopt(TO_SOCKET(s), level, optname, optval, optlen); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef shutdown int WSAAPI rb_w32_shutdown(int s, int how) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = shutdown(TO_SOCKET(s), how); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } static SOCKET open_ifs_socket(int af, int type, int protocol) { unsigned long proto_buffers_len = 0; int error_code; SOCKET out = INVALID_SOCKET; if (WSAEnumProtocols(NULL, NULL, &proto_buffers_len) == SOCKET_ERROR) { error_code = WSAGetLastError(); if (error_code == WSAENOBUFS) { WSAPROTOCOL_INFO *proto_buffers; int protocols_available = 0; proto_buffers = (WSAPROTOCOL_INFO *)malloc(proto_buffers_len); if (!proto_buffers) { WSASetLastError(WSA_NOT_ENOUGH_MEMORY); return INVALID_SOCKET; } protocols_available = WSAEnumProtocols(NULL, proto_buffers, &proto_buffers_len); if (protocols_available != SOCKET_ERROR) { int i; for (i = 0; i < protocols_available; i++) { if ((af != AF_UNSPEC && af != proto_buffers[i].iAddressFamily) || (type != proto_buffers[i].iSocketType) || (protocol != 0 && protocol != proto_buffers[i].iProtocol)) continue; if ((proto_buffers[i].dwServiceFlags1 & XP1_IFS_HANDLES) == 0) continue; out = WSASocket(af, type, protocol, &(proto_buffers[i]), 0, WSA_FLAG_OVERLAPPED); break; } if (out == INVALID_SOCKET) out = WSASocket(af, type, protocol, NULL, 0, 0); } free(proto_buffers); } } return out; } #undef socket int WSAAPI rb_w32_socket(int af, int type, int protocol) { SOCKET s; int fd; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ s = open_ifs_socket(af, type, protocol); if (s == INVALID_SOCKET) { errno = map_errno(WSAGetLastError()); fd = -1; } else { fd = rb_w32_open_osfhandle(s, O_RDWR|O_BINARY|O_NOINHERIT); if (fd != -1) st_insert(socklist, (st_data_t)s, (st_data_t)0); else closesocket(s); } }); return fd; } #undef gethostbyaddr struct hostent * WSAAPI rb_w32_gethostbyaddr(const char *addr, int len, int type) { struct hostent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = gethostbyaddr(addr, len, type); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } #undef gethostbyname struct hostent * WSAAPI rb_w32_gethostbyname(const char *name) { struct hostent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = gethostbyname(name); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } #undef gethostname int WSAAPI rb_w32_gethostname(char *name, int len) { int r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = gethostname(name, len); if (r == SOCKET_ERROR) errno = map_errno(WSAGetLastError()); }); return r; } #undef getprotobyname struct protoent * WSAAPI rb_w32_getprotobyname(const char *name) { struct protoent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getprotobyname(name); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } #undef getprotobynumber struct protoent * WSAAPI rb_w32_getprotobynumber(int num) { struct protoent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getprotobynumber(num); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } #undef getservbyname struct servent * WSAAPI rb_w32_getservbyname(const char *name, const char *proto) { struct servent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getservbyname(name, proto); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } #undef getservbyport struct servent * WSAAPI rb_w32_getservbyport(int port, const char *proto) { struct servent *r; if (!NtSocketsInitialized) { StartSockets(); } RUBY_CRITICAL({ r = getservbyport(port, proto); if (r == NULL) errno = map_errno(WSAGetLastError()); }); return r; } static int socketpair_internal(int af, int type, int protocol, SOCKET *sv) { SOCKET svr = INVALID_SOCKET, r = INVALID_SOCKET, w = INVALID_SOCKET; struct sockaddr_in sock_in4; #ifdef INET6 struct sockaddr_in6 sock_in6; #endif struct sockaddr *addr; int ret = -1; int len; if (!NtSocketsInitialized) { StartSockets(); } switch (af) { case AF_INET: #if defined PF_INET && PF_INET != AF_INET case PF_INET: #endif sock_in4.sin_family = AF_INET; sock_in4.sin_port = 0; sock_in4.sin_addr.s_addr = htonl(INADDR_LOOPBACK); addr = (struct sockaddr *)&sock_in4; len = sizeof(sock_in4); break; #ifdef INET6 case AF_INET6: memset(&sock_in6, 0, sizeof(sock_in6)); sock_in6.sin6_family = AF_INET6; sock_in6.sin6_addr = IN6ADDR_LOOPBACK_INIT; addr = (struct sockaddr *)&sock_in6; len = sizeof(sock_in6); break; #endif default: errno = EAFNOSUPPORT; return -1; } if (type != SOCK_STREAM) { errno = EPROTOTYPE; return -1; } RUBY_CRITICAL({ do { svr = open_ifs_socket(af, type, protocol); if (svr == INVALID_SOCKET) break; if (bind(svr, addr, len) < 0) break; if (getsockname(svr, addr, &len) < 0) break; if (type == SOCK_STREAM) listen(svr, 5); w = open_ifs_socket(af, type, protocol); if (w == INVALID_SOCKET) break; if (connect(w, addr, len) < 0) break; r = accept(svr, addr, &len); if (r == INVALID_SOCKET) break; ret = 0; } while (0); if (ret < 0) { errno = map_errno(WSAGetLastError()); if (r != INVALID_SOCKET) closesocket(r); if (w != INVALID_SOCKET) closesocket(w); } else { sv[0] = r; sv[1] = w; } if (svr != INVALID_SOCKET) closesocket(svr); }); return ret; } int rb_w32_socketpair(int af, int type, int protocol, int *sv) { SOCKET pair[2]; if (socketpair_internal(af, type, protocol, pair) < 0) return -1; sv[0] = rb_w32_open_osfhandle(pair[0], O_RDWR|O_BINARY|O_NOINHERIT); if (sv[0] == -1) { closesocket(pair[0]); closesocket(pair[1]); return -1; } sv[1] = rb_w32_open_osfhandle(pair[1], O_RDWR|O_BINARY|O_NOINHERIT); if (sv[1] == -1) { rb_w32_close(sv[0]); closesocket(pair[1]); return -1; } st_insert(socklist, (st_data_t)pair[0], (st_data_t)0); st_insert(socklist, (st_data_t)pair[1], (st_data_t)0); return 0; } // // Networking stubs // void endhostent(void) {} void endnetent(void) {} void endprotoent(void) {} void endservent(void) {} struct netent *getnetent (void) {return (struct netent *) NULL;} struct netent *getnetbyaddr(long net, int type) {return (struct netent *)NULL;} struct netent *getnetbyname(const char *name) {return (struct netent *)NULL;} struct protoent *getprotoent (void) {return (struct protoent *) NULL;} struct servent *getservent (void) {return (struct servent *) NULL;} void sethostent (int stayopen) {} void setnetent (int stayopen) {} void setprotoent (int stayopen) {} void setservent (int stayopen) {} int fcntl(int fd, int cmd, ...) { SOCKET sock = TO_SOCKET(fd); va_list va; int arg; int ret; int flag = 0; st_data_t data; u_long ioctlArg; if (!is_socket(sock)) { errno = EBADF; return -1; } if (cmd != F_SETFL) { errno = EINVAL; return -1; } va_start(va, cmd); arg = va_arg(va, int); va_end(va); st_lookup(socklist, (st_data_t)sock, &data); flag = (int)data; if (arg & O_NONBLOCK) { flag |= O_NONBLOCK; ioctlArg = 1; } else { flag &= ~O_NONBLOCK; ioctlArg = 0; } RUBY_CRITICAL({ ret = ioctlsocket(sock, FIONBIO, &ioctlArg); if (ret == 0) st_insert(socklist, (st_data_t)sock, (st_data_t)flag); else errno = map_errno(WSAGetLastError()); }); return ret; } #ifndef WNOHANG #define WNOHANG -1 #endif static rb_pid_t poll_child_status(struct ChildRecord *child, int *stat_loc) { DWORD exitcode; DWORD err; if (!GetExitCodeProcess(child->hProcess, &exitcode)) { /* If an error occured, return immediatly. */ err = GetLastError(); if (err == ERROR_INVALID_PARAMETER) errno = ECHILD; else { if (GetLastError() == ERROR_INVALID_HANDLE) errno = EINVAL; else errno = map_errno(GetLastError()); } CloseChildHandle(child); return -1; } if (exitcode != STILL_ACTIVE) { /* If already died, return immediatly. */ rb_pid_t pid = child->pid; CloseChildHandle(child); if (stat_loc) *stat_loc = exitcode << 8; return pid; } return 0; } rb_pid_t waitpid(rb_pid_t pid, int *stat_loc, int options) { DWORD timeout; if (options == WNOHANG) { timeout = 0; } else { timeout = INFINITE; } if (pid == -1) { int count = 0; int ret; HANDLE events[MAXCHILDNUM]; FOREACH_CHILD(child) { if (!child->pid || child->pid < 0) continue; if ((pid = poll_child_status(child, stat_loc))) return pid; events[count++] = child->hProcess; } END_FOREACH_CHILD; if (!count) { errno = ECHILD; return -1; } ret = rb_w32_wait_events_blocking(events, count, timeout); if (ret == WAIT_TIMEOUT) return 0; if ((ret -= WAIT_OBJECT_0) == count) { return -1; } if (ret > count) { errno = map_errno(GetLastError()); return -1; } return poll_child_status(FindChildSlotByHandle(events[ret]), stat_loc); } else { struct ChildRecord* child = FindChildSlot(pid); if (!child) { errno = ECHILD; return -1; } while (!(pid = poll_child_status(child, stat_loc))) { /* wait... */ if (rb_w32_wait_events_blocking(&child->hProcess, 1, timeout) != WAIT_OBJECT_0) { /* still active */ pid = 0; break; } } } return pid; } #include static int filetime_to_timeval(const FILETIME* ft, struct timeval *tv) { ULARGE_INTEGER tmp; unsigned LONG_LONG lt; tmp.LowPart = ft->dwLowDateTime; tmp.HighPart = ft->dwHighDateTime; lt = tmp.QuadPart; /* lt is now 100-nanosec intervals since 1601/01/01 00:00:00 UTC, convert it into UNIX time (since 1970/01/01 00:00:00 UTC). the first leap second is at 1972/06/30, so we doesn't need to think about it. */ lt /= 10; /* to usec */ lt -= (LONG_LONG)((1970-1601)*365.2425) * 24 * 60 * 60 * 1000 * 1000; tv->tv_sec = (long)(lt / (1000 * 1000)); tv->tv_usec = (long)(lt % (1000 * 1000)); return tv->tv_sec > 0 ? 0 : -1; } int _cdecl gettimeofday(struct timeval *tv, struct timezone *tz) { FILETIME ft; GetSystemTimeAsFileTime(&ft); filetime_to_timeval(&ft, tv); return 0; } char * rb_w32_getcwd(char *buffer, int size) { char *p = buffer; char *bp; int len; len = GetCurrentDirectory(0, NULL); if (!len) { errno = map_errno(GetLastError()); return NULL; } if (p) { if (size < len) { errno = ERANGE; return NULL; } } else { p = malloc(len); size = len; if (!p) { errno = ENOMEM; return NULL; } } if (!GetCurrentDirectory(size, p)) { errno = map_errno(GetLastError()); if (!buffer) free(p); return NULL; } for (bp = p; *bp != '\0'; bp = CharNext(bp)) { if (*bp == '\\') { *bp = '/'; } } return p; } int chown(const char *path, int owner, int group) { return 0; } int kill(int pid, int sig) { int ret = 0; DWORD err; if (pid <= 0) { errno = EINVAL; return -1; } (void)IfWin95(pid = -pid, 0); if ((unsigned int)pid == GetCurrentProcessId() && (sig != 0 && sig != SIGKILL)) { if ((ret = raise(sig)) != 0) { /* MSVCRT doesn't set errno... */ errno = EINVAL; } return ret; } switch (sig) { case 0: RUBY_CRITICAL({ HANDLE hProc = OpenProcess(PROCESS_QUERY_INFORMATION, FALSE, (DWORD)pid); if (hProc == NULL || hProc == INVALID_HANDLE_VALUE) { if (GetLastError() == ERROR_INVALID_PARAMETER) { errno = ESRCH; } else { errno = EPERM; } ret = -1; } else { CloseHandle(hProc); } }); break; case SIGINT: RUBY_CRITICAL({ if (!GenerateConsoleCtrlEvent(CTRL_C_EVENT, (DWORD)pid)) { if ((err = GetLastError()) == 0) errno = EPERM; else errno = map_errno(GetLastError()); ret = -1; } }); break; case SIGKILL: RUBY_CRITICAL({ HANDLE hProc = OpenProcess(PROCESS_TERMINATE, FALSE, (DWORD)pid); if (hProc == NULL || hProc == INVALID_HANDLE_VALUE) { if (GetLastError() == ERROR_INVALID_PARAMETER) { errno = ESRCH; } else { errno = EPERM; } ret = -1; } else { if (!TerminateProcess(hProc, 0)) { errno = EPERM; ret = -1; } CloseHandle(hProc); } }); break; default: errno = EINVAL; ret = -1; break; } return ret; } int link(const char *from, const char *to) { static BOOL (WINAPI *pCreateHardLink)(LPCTSTR, LPCTSTR, LPSECURITY_ATTRIBUTES) = NULL; static int myerrno = 0; if (!pCreateHardLink && !myerrno) { HANDLE hKernel; hKernel = GetModuleHandle("kernel32.dll"); if (hKernel) { pCreateHardLink = (BOOL (WINAPI *)(LPCTSTR, LPCTSTR, LPSECURITY_ATTRIBUTES))GetProcAddress(hKernel, "CreateHardLinkA"); if (!pCreateHardLink) { myerrno = ENOSYS; } } else { myerrno = map_errno(GetLastError()); } } if (!pCreateHardLink) { errno = myerrno; return -1; } if (!pCreateHardLink(to, from, NULL)) { errno = map_errno(GetLastError()); return -1; } return 0; } int wait(int *status) { return waitpid(-1, status, 0); } char * rb_w32_getenv(const char *name) { int len = strlen(name); char *env; if (envarea) FreeEnvironmentStrings(envarea); envarea = GetEnvironmentStrings(); if (!envarea) { map_errno(GetLastError()); return NULL; } for (env = envarea; *env; env += strlen(env) + 1) if (strncasecmp(env, name, len) == 0 && *(env + len) == '=') return env + len + 1; return NULL; } int rb_w32_rename(const char *oldpath, const char *newpath) { int res = 0; int oldatts; int newatts; oldatts = GetFileAttributes(oldpath); newatts = GetFileAttributes(newpath); if (oldatts == -1) { errno = map_errno(GetLastError()); return -1; } RUBY_CRITICAL({ if (newatts != -1 && newatts & FILE_ATTRIBUTE_READONLY) SetFileAttributesA(newpath, newatts & ~ FILE_ATTRIBUTE_READONLY); if (!MoveFile(oldpath, newpath)) res = -1; if (res) { switch (GetLastError()) { case ERROR_ALREADY_EXISTS: case ERROR_FILE_EXISTS: if (IsWinNT()) { if (MoveFileEx(oldpath, newpath, MOVEFILE_REPLACE_EXISTING)) res = 0; } else { for (;;) { if (!DeleteFile(newpath) && GetLastError() != ERROR_FILE_NOT_FOUND) break; else if (MoveFile(oldpath, newpath)) { res = 0; break; } } } } } if (res) errno = map_errno(GetLastError()); else SetFileAttributes(newpath, oldatts); }); return res; } static int isUNCRoot(const char *path) { if (path[0] == '\\' && path[1] == '\\') { const char *p; for (p = path + 2; *p; p = CharNext(p)) { if (*p == '\\') break; } if (p[0] && p[1]) { for (p++; *p; p = CharNext(p)) { if (*p == '\\') break; } if (!p[0] || !p[1] || (p[1] == '.' && !p[2])) return 1; } } return 0; } #define COPY_STAT(src, dest, size_cast) do { \ (dest).st_dev = (src).st_dev; \ (dest).st_ino = (src).st_ino; \ (dest).st_mode = (src).st_mode; \ (dest).st_nlink = (src).st_nlink; \ (dest).st_uid = (src).st_uid; \ (dest).st_gid = (src).st_gid; \ (dest).st_rdev = (src).st_rdev; \ (dest).st_size = size_cast(src).st_size; \ (dest).st_atime = (src).st_atime; \ (dest).st_mtime = (src).st_mtime; \ (dest).st_ctime = (src).st_ctime; \ } while (0) #ifdef __BORLANDC__ #undef fstat int rb_w32_fstat(int fd, struct stat *st) { BY_HANDLE_FILE_INFORMATION info; int ret = fstat(fd, st); if (ret) return ret; st->st_mode &= ~(S_IWGRP | S_IWOTH); if (GetFileInformationByHandle((HANDLE)_get_osfhandle(fd), &info) && !(info.dwFileAttributes & FILE_ATTRIBUTE_READONLY)) { st->st_mode |= S_IWUSR; } return ret; } int rb_w32_fstati64(int fd, struct stati64 *st) { BY_HANDLE_FILE_INFORMATION info; struct stat tmp; int ret = fstat(fd, &tmp); if (ret) return ret; tmp.st_mode &= ~(S_IWGRP | S_IWOTH); COPY_STAT(tmp, *st, +); if (GetFileInformationByHandle((HANDLE)_get_osfhandle(fd), &info)) { if (!(info.dwFileAttributes & FILE_ATTRIBUTE_READONLY)) { st->st_mode |= S_IWUSR; } st->st_size = ((__int64)info.nFileSizeHigh << 32) | info.nFileSizeLow; } return ret; } #endif static time_t filetime_to_unixtime(const FILETIME *ft) { struct timeval tv; if (filetime_to_timeval(ft, &tv) == (time_t)-1) return 0; else return tv.tv_sec; } static unsigned fileattr_to_unixmode(DWORD attr, const char *path) { unsigned mode = 0; if (attr & FILE_ATTRIBUTE_READONLY) { mode |= S_IREAD; } else { mode |= S_IREAD | S_IWRITE | S_IWUSR; } if (attr & FILE_ATTRIBUTE_DIRECTORY) { mode |= S_IFDIR | S_IEXEC; } else { mode |= S_IFREG; } if (path && (mode & S_IFREG)) { const char *end = path + strlen(path); while (path < end) { end = CharPrev(path, end); if (*end == '.') { if ((strcasecmp(end, ".bat") == 0) || (strcasecmp(end, ".cmd") == 0) || (strcasecmp(end, ".com") == 0) || (strcasecmp(end, ".exe") == 0)) { mode |= S_IEXEC; } break; } } } mode |= (mode & 0700) >> 3; mode |= (mode & 0700) >> 6; return mode; } static int check_valid_dir(const char *path) { WIN32_FIND_DATAW fd; HANDLE fh = open_dir_handle(path, &fd); if (fh == INVALID_HANDLE_VALUE) return -1; FindClose(fh); return 0; } static int winnt_stat(const char *path, struct stati64 *st) { HANDLE h; WIN32_FIND_DATA wfd; memset(st, 0, sizeof(*st)); st->st_nlink = 1; if (_mbspbrk((const unsigned char *)path, (const unsigned char *)"?*")) { errno = ENOENT; return -1; } h = FindFirstFile(path, &wfd); if (h != INVALID_HANDLE_VALUE) { FindClose(h); st->st_mode = fileattr_to_unixmode(wfd.dwFileAttributes, path); st->st_atime = filetime_to_unixtime(&wfd.ftLastAccessTime); st->st_mtime = filetime_to_unixtime(&wfd.ftLastWriteTime); st->st_ctime = filetime_to_unixtime(&wfd.ftCreationTime); st->st_size = ((__int64)wfd.nFileSizeHigh << 32) | wfd.nFileSizeLow; } else { // If runtime stat(2) is called for network shares, it fails on WinNT. // Because GetDriveType returns 1 for network shares. (Win98 returns 4) DWORD attr = GetFileAttributes(path); if (attr == (DWORD)-1L) { errno = map_errno(GetLastError()); return -1; } if (attr & FILE_ATTRIBUTE_DIRECTORY) { if (check_valid_dir(path)) return -1; } st->st_mode = fileattr_to_unixmode(attr, path); } st->st_dev = st->st_rdev = (isalpha(path[0]) && path[1] == ':') ? toupper(path[0]) - 'A' : _getdrive() - 1; return 0; } #ifdef WIN95 static int win95_stat(const char *path, struct stati64 *st) { int ret = stati64(path, st); if (ret) return ret; if (st->st_mode & S_IFDIR) { return check_valid_dir(path); } return 0; } #else #define win95_stat(path, st) -1 #endif int rb_w32_stat(const char *path, struct stat *st) { struct stati64 tmp; if (rb_w32_stati64(path, &tmp)) return -1; COPY_STAT(tmp, *st, (_off_t)); return 0; } int rb_w32_stati64(const char *path, struct stati64 *st) { const char *p; char *buf1, *s, *end; int len, size; int ret; if (!path || !st) { errno = EFAULT; return -1; } size = strlen(path) + 2; buf1 = ALLOCA_N(char, size); for (p = path, s = buf1; *p; p++, s++) { if (*p == '/') *s = '\\'; else *s = *p; } *s = '\0'; len = s - buf1; if (!len || '\"' == *(--s)) { errno = ENOENT; return -1; } end = CharPrev(buf1, buf1 + len); if (isUNCRoot(buf1)) { if (*end == '.') *end = '\0'; else if (*end != '\\') strlcat(buf1, "\\", size); } else if (*end == '\\' || (buf1 + 1 == end && *end == ':')) strlcat(buf1, ".", size); ret = IsWinNT() ? winnt_stat(buf1, st) : win95_stat(buf1, st); if (ret == 0) { st->st_mode &= ~(S_IWGRP | S_IWOTH); } return ret; } int rb_w32_access(const char *path, int mode) { struct stati64 stat; if (rb_w32_stati64(path, &stat) != 0) return -1; mode <<= 6; if ((stat.st_mode & mode) != mode) { errno = EACCES; return -1; } return 0; } static int rb_chsize(HANDLE h, off_t size) { long upos, lpos, usize, lsize, uend, lend; off_t end; int ret = -1; DWORD e; if (((lpos = SetFilePointer(h, 0, (upos = 0, &upos), SEEK_CUR)) == -1L && (e = GetLastError())) || ((lend = GetFileSize(h, (DWORD *)&uend)) == -1L && (e = GetLastError()))) { errno = map_errno(e); return -1; } end = ((off_t)uend << 32) | (unsigned long)lend; usize = (long)(size >> 32); lsize = (long)size; if (SetFilePointer(h, lsize, &usize, SEEK_SET) == (DWORD)-1L && (e = GetLastError())) { errno = map_errno(e); } else if (!SetEndOfFile(h)) { errno = map_errno(GetLastError()); } else { ret = 0; } SetFilePointer(h, lpos, &upos, SEEK_SET); return ret; } int truncate(const char *path, off_t length) { HANDLE h; int ret; #ifdef WIN95 if (IsWin95()) { int fd = open(path, O_WRONLY), e = 0; if (fd == -1) return -1; ret = chsize(fd, (unsigned long)length); if (ret == -1) e = errno; close(fd); if (ret == -1) errno = e; return ret; } #endif h = CreateFile(path, GENERIC_WRITE, 0, 0, OPEN_EXISTING, 0, 0); if (h == INVALID_HANDLE_VALUE) { errno = map_errno(GetLastError()); return -1; } ret = rb_chsize(h, length); CloseHandle(h); return ret; } int ftruncate(int fd, off_t length) { long h; #ifdef WIN95 if (IsWin95()) { return chsize(fd, (unsigned long)length); } #endif h = _get_osfhandle(fd); if (h == -1) return -1; return rb_chsize((HANDLE)h, length); } #ifdef __BORLANDC__ off_t _filelengthi64(int fd) { DWORD u, l; int e; l = GetFileSize((HANDLE)_get_osfhandle(fd), &u); if (l == (DWORD)-1L && (e = GetLastError())) { errno = map_errno(e); return (off_t)-1; } return ((off_t)u << 32) | l; } off_t _lseeki64(int fd, off_t offset, int whence) { long u, l; int e; HANDLE h = (HANDLE)_get_osfhandle(fd); if (!h) { errno = EBADF; return -1; } u = (long)(offset >> 32); if ((l = SetFilePointer(h, (long)offset, &u, whence)) == -1L && (e = GetLastError())) { errno = map_errno(e); return -1; } return ((off_t)u << 32) | l; } #endif int fseeko(FILE *stream, off_t offset, int whence) { off_t pos; switch (whence) { case SEEK_CUR: if (fgetpos(stream, (fpos_t *)&pos)) return -1; pos += offset; break; case SEEK_END: if ((pos = _filelengthi64(fileno(stream))) == (off_t)-1) return -1; pos += offset; break; default: pos = offset; break; } return fsetpos(stream, (fpos_t *)&pos); } off_t ftello(FILE *stream) { off_t pos; if (fgetpos(stream, (fpos_t *)&pos)) return (off_t)-1; return pos; } static long filetime_to_clock(FILETIME *ft) { __int64 qw = ft->dwHighDateTime; qw <<= 32; qw |= ft->dwLowDateTime; qw /= 10000; /* File time ticks at 0.1uS, clock at 1mS */ return (long) qw; } int rb_w32_times(struct tms *tmbuf) { FILETIME create, exit, kernel, user; if (GetProcessTimes(GetCurrentProcess(),&create, &exit, &kernel, &user)) { tmbuf->tms_utime = filetime_to_clock(&user); tmbuf->tms_stime = filetime_to_clock(&kernel); tmbuf->tms_cutime = 0; tmbuf->tms_cstime = 0; } else { tmbuf->tms_utime = clock(); tmbuf->tms_stime = 0; tmbuf->tms_cutime = 0; tmbuf->tms_cstime = 0; } return 0; } #define yield_once() Sleep(0) #define yield_until(condition) do yield_once(); while (!(condition)) static void catch_interrupt(void) { yield_once(); RUBY_CRITICAL(rb_w32_wait_events(NULL, 0, 0)); } #if defined __BORLANDC__ #undef read int read(int fd, void *buf, size_t size) { int ret = _read(fd, buf, size); if ((ret < 0) && (errno == EPIPE)) { errno = 0; ret = 0; } catch_interrupt(); return ret; } #endif #undef fgetc int rb_w32_getc(FILE* stream) { int c; if (enough_to_get(stream->FILE_COUNT)) { c = (unsigned char)*stream->FILE_READPTR++; } else { c = _filbuf(stream); #if defined __BORLANDC__ if ((c == EOF) && (errno == EPIPE)) { clearerr(stream); } #endif catch_interrupt(); } return c; } #undef fputc int rb_w32_putc(int c, FILE* stream) { if (enough_to_put(stream->FILE_COUNT)) { c = (unsigned char)(*stream->FILE_READPTR++ = (char)c); } else { c = _flsbuf(c, stream); catch_interrupt(); } return c; } struct asynchronous_arg_t { /* output field */ void* stackaddr; int errnum; /* input field */ uintptr_t (*func)(uintptr_t self, int argc, uintptr_t* argv); uintptr_t self; int argc; uintptr_t* argv; }; static DWORD WINAPI call_asynchronous(PVOID argp) { DWORD ret; struct asynchronous_arg_t *arg = argp; arg->stackaddr = &argp; ret = (DWORD)arg->func(arg->self, arg->argc, arg->argv); arg->errnum = errno; return ret; } uintptr_t rb_w32_asynchronize(asynchronous_func_t func, uintptr_t self, int argc, uintptr_t* argv, uintptr_t intrval) { DWORD val; BOOL interrupted = FALSE; HANDLE thr; RUBY_CRITICAL({ struct asynchronous_arg_t arg; arg.stackaddr = NULL; arg.errnum = 0; arg.func = func; arg.self = self; arg.argc = argc; arg.argv = argv; thr = CreateThread(NULL, 0, call_asynchronous, &arg, 0, &val); if (thr) { yield_until(arg.stackaddr); if (rb_w32_wait_events_blocking(&thr, 1, INFINITE) != WAIT_OBJECT_0) { interrupted = TRUE; if (TerminateThread(thr, intrval)) { yield_once(); } } GetExitCodeThread(thr, &val); CloseHandle(thr); if (interrupted) { /* must release stack of killed thread, why doesn't Windows? */ MEMORY_BASIC_INFORMATION m; memset(&m, 0, sizeof(m)); if (!VirtualQuery(arg.stackaddr, &m, sizeof(m))) { Debug(fprintf(stderr, "couldn't get stack base:%p:%d\n", arg.stackaddr, GetLastError())); } else if (!VirtualFree(m.AllocationBase, 0, MEM_RELEASE)) { Debug(fprintf(stderr, "couldn't release stack:%p:%d\n", m.AllocationBase, GetLastError())); } errno = EINTR; } else { errno = arg.errnum; } } }); if (!thr) { rb_fatal("failed to launch waiter thread:%ld", GetLastError()); } return val; } char ** rb_w32_get_environ(void) { char *envtop, *env; char **myenvtop, **myenv; int num; /* * We avoid values started with `='. If you want to deal those values, * change this function, and some functions in hash.c which recognize * `=' as delimiter or rb_w32_getenv() and ruby_setenv(). * CygWin deals these values by changing first `=' to '!'. But we don't * use such trick and follow cmd.exe's way that just doesn't show these * values. * (U.N. 2001-11-15) */ envtop = GetEnvironmentStrings(); for (env = envtop, num = 0; *env; env += strlen(env) + 1) if (*env != '=') num++; myenvtop = (char **)malloc(sizeof(char *) * (num + 1)); for (env = envtop, myenv = myenvtop; *env; env += strlen(env) + 1) { if (*env != '=') { if (!(*myenv = strdup(env))) { break; } myenv++; } } *myenv = NULL; FreeEnvironmentStrings(envtop); return myenvtop; } void rb_w32_free_environ(char **env) { char **t = env; while (*t) free(*t++); free(env); } rb_pid_t rb_w32_getpid(void) { rb_pid_t pid; pid = GetCurrentProcessId(); (void)IfWin95(pid = -pid, 0); return pid; } rb_pid_t rb_w32_getppid(void) { static long (WINAPI *pNtQueryInformationProcess)(HANDLE, int, void *, ULONG, ULONG *) = NULL; rb_pid_t ppid = 0; if (!IsWin95() && rb_w32_osver() >= 5) { if (!pNtQueryInformationProcess) { HANDLE hNtDll = GetModuleHandle("ntdll.dll"); if (hNtDll) { pNtQueryInformationProcess = (long (WINAPI *)(HANDLE, int, void *, ULONG, ULONG *))GetProcAddress(hNtDll, "NtQueryInformationProcess"); } } if (pNtQueryInformationProcess) { struct { long ExitStatus; void* PebBaseAddress; ULONG AffinityMask; ULONG BasePriority; ULONG UniqueProcessId; ULONG ParentProcessId; } pbi; ULONG len; long ret = pNtQueryInformationProcess(GetCurrentProcess(), 0, &pbi, sizeof(pbi), &len); if (!ret) { ppid = pbi.ParentProcessId; } } } return ppid; } int rb_w32_open(const char *file, int oflag, ...) { UINT cp = AreFileApisANSI() ? CP_ACP : CP_OEMCP; int len; WCHAR *wfile; int pmode; va_list arg; va_start(arg, oflag); pmode = va_arg(arg, int); va_end(arg); if ((oflag & O_TEXT) || !(oflag & O_BINARY)) { return _open(file, oflag, pmode); } len = MultiByteToWideChar(cp, 0, file, -1, NULL, 0); if (len <= 0) { errno = map_errno(GetLastError()); return -1; } wfile = ALLOCA_N(WCHAR, len); MultiByteToWideChar(cp, 0, file, -1, wfile, len); if (len <= 0) { errno = map_errno(GetLastError()); return -1; } return rb_w32_wopen(wfile, oflag, pmode); } int rb_w32_wopen(const WCHAR *file, int oflag, ...) { char flags = 0; int fd; DWORD access; DWORD create; DWORD attr = FILE_ATTRIBUTE_NORMAL; SECURITY_ATTRIBUTES sec; HANDLE h; if ((oflag & O_TEXT) || !(oflag & O_BINARY)) { va_list arg; int pmode; va_start(arg, oflag); pmode = va_arg(arg, int); va_end(arg); return _wopen(file, oflag, pmode); } sec.nLength = sizeof(sec); sec.lpSecurityDescriptor = NULL; if (oflag & O_NOINHERIT) { sec.bInheritHandle = FALSE; flags |= FNOINHERIT; } else { sec.bInheritHandle = TRUE; } oflag &= ~O_NOINHERIT; /* always open with binary mode */ oflag &= ~(O_BINARY | O_TEXT); switch (oflag & (O_RDWR | O_RDONLY | O_WRONLY)) { case O_RDWR: access = GENERIC_READ | GENERIC_WRITE; break; case O_RDONLY: access = GENERIC_READ; break; case O_WRONLY: access = GENERIC_WRITE; break; default: errno = EINVAL; return -1; } oflag &= ~(O_RDWR | O_RDONLY | O_WRONLY); switch (oflag & (O_CREAT | O_EXCL | O_TRUNC)) { case O_CREAT: create = OPEN_ALWAYS; break; case 0: case O_EXCL: create = OPEN_EXISTING; break; case O_CREAT | O_EXCL: case O_CREAT | O_EXCL | O_TRUNC: create = CREATE_NEW; break; case O_TRUNC: case O_TRUNC | O_EXCL: create = TRUNCATE_EXISTING; break; case O_CREAT | O_TRUNC: create = CREATE_ALWAYS; break; default: errno = EINVAL; return -1; } if (oflag & O_CREAT) { va_list arg; int pmode; va_start(arg, oflag); pmode = va_arg(arg, int); va_end(arg); /* TODO: we need to check umask here, but it's not exported... */ if (!(pmode & S_IWRITE)) attr = FILE_ATTRIBUTE_READONLY; } oflag &= ~(O_CREAT | O_EXCL | O_TRUNC); if (oflag & O_TEMPORARY) { attr |= FILE_FLAG_DELETE_ON_CLOSE; access |= DELETE; } oflag &= ~O_TEMPORARY; if (oflag & _O_SHORT_LIVED) attr |= FILE_ATTRIBUTE_TEMPORARY; oflag &= ~_O_SHORT_LIVED; switch (oflag & (O_SEQUENTIAL | O_RANDOM)) { case 0: break; case O_SEQUENTIAL: attr |= FILE_FLAG_SEQUENTIAL_SCAN; break; case O_RANDOM: attr |= FILE_FLAG_RANDOM_ACCESS; break; default: errno = EINVAL; return -1; } oflag &= ~(O_SEQUENTIAL | O_RANDOM); if (oflag & ~O_APPEND) { errno = EINVAL; return -1; } /* allocate a C Runtime file handle */ RUBY_CRITICAL({ h = CreateFile("NUL", 0, 0, NULL, OPEN_ALWAYS, 0, NULL); fd = _open_osfhandle((long)h, 0); CloseHandle(h); }); if (fd == -1) { errno = EMFILE; return -1; } RUBY_CRITICAL({ MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fd)->lock))); _set_osfhnd(fd, (long)INVALID_HANDLE_VALUE); _set_osflags(fd, 0); /* open with FILE_FLAG_OVERLAPPED if have CancelIo */ if (cancel_io) attr |= FILE_FLAG_OVERLAPPED; h = CreateFileW(file, access, FILE_SHARE_READ | FILE_SHARE_WRITE, &sec, create, attr, NULL); if (h == INVALID_HANDLE_VALUE) { errno = map_errno(GetLastError()); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); fd = -1; goto quit; } switch (GetFileType(h)) { case FILE_TYPE_CHAR: flags |= FDEV; break; case FILE_TYPE_PIPE: flags |= FPIPE; break; case FILE_TYPE_UNKNOWN: errno = map_errno(GetLastError()); CloseHandle(h); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); fd = -1; goto quit; } if (!(flags & (FDEV | FPIPE)) && (oflag & O_APPEND)) flags |= FAPPEND; _set_osfhnd(fd, (long)h); _osfile(fd) = flags | FOPEN; MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); quit: ; }); return fd; } int rb_w32_fclose(FILE *fp) { int fd = fileno(fp); SOCKET sock = TO_SOCKET(fd); int save_errno = errno; if (fflush(fp)) return -1; if (!is_socket(sock)) { UnlockFile((HANDLE)sock, 0, 0, LK_LEN, LK_LEN); return fclose(fp); } _set_osfhnd(fd, (SOCKET)INVALID_HANDLE_VALUE); fclose(fp); errno = save_errno; if (closesocket(sock) == SOCKET_ERROR) { errno = map_errno(WSAGetLastError()); return -1; } return 0; } int rb_w32_pipe(int fds[2]) { static DWORD serial = 0; char name[] = "\\\\.\\pipe\\ruby0000000000000000-0000000000000000"; char *p; SECURITY_ATTRIBUTES sec; HANDLE hRead, hWrite, h; int fdRead, fdWrite; int ret; /* if doesn't have CancelIo, use default pipe function */ if (!cancel_io) return _pipe(fds, 65536L, _O_NOINHERIT); p = strchr(name, '0'); snprintf(p, strlen(p) + 1, "%x-%lx", rb_w32_getpid(), serial++); sec.nLength = sizeof(sec); sec.lpSecurityDescriptor = NULL; sec.bInheritHandle = FALSE; RUBY_CRITICAL({ hRead = CreateNamedPipe(name, PIPE_ACCESS_DUPLEX | FILE_FLAG_OVERLAPPED, 0, 2, 65536, 65536, 0, &sec); }); if (hRead == INVALID_HANDLE_VALUE) { DWORD err = GetLastError(); if (err == ERROR_PIPE_BUSY) errno = EMFILE; else errno = map_errno(GetLastError()); return -1; } RUBY_CRITICAL({ hWrite = CreateFile(name, GENERIC_READ | GENERIC_WRITE, 0, &sec, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL); }); if (hWrite == INVALID_HANDLE_VALUE) { errno = map_errno(GetLastError()); CloseHandle(hRead); return -1; } RUBY_CRITICAL(do { ret = 0; h = CreateFile("NUL", 0, 0, NULL, OPEN_ALWAYS, 0, NULL); fdRead = _open_osfhandle((long)h, 0); CloseHandle(h); if (fdRead == -1) { errno = EMFILE; CloseHandle(hWrite); CloseHandle(hRead); ret = -1; break; } MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fdRead)->lock))); _set_osfhnd(fdRead, (long)hRead); _set_osflags(fdRead, FOPEN | FPIPE | FNOINHERIT); MTHREAD_ONLY(LeaveCriticalSection(&(_pioinfo(fdRead)->lock))); } while (0)); if (ret) return ret; RUBY_CRITICAL(do { h = CreateFile("NUL", 0, 0, NULL, OPEN_ALWAYS, 0, NULL); fdWrite = _open_osfhandle((long)h, 0); CloseHandle(h); if (fdWrite == -1) { errno = EMFILE; CloseHandle(hWrite); ret = -1; break; } MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fdWrite)->lock))); _set_osfhnd(fdWrite, (long)hWrite); _set_osflags(fdWrite, FOPEN | FPIPE | FNOINHERIT); MTHREAD_ONLY(LeaveCriticalSection(&(_pioinfo(fdWrite)->lock))); } while (0)); if (ret) { rb_w32_close(fdRead); return ret; } fds[0] = fdRead; fds[1] = fdWrite; return 0; } int rb_w32_close(int fd) { SOCKET sock = TO_SOCKET(fd); int save_errno = errno; st_data_t key; if (!is_socket(sock)) { UnlockFile((HANDLE)sock, 0, 0, LK_LEN, LK_LEN); return _close(fd); } _set_osfhnd(fd, (SOCKET)INVALID_HANDLE_VALUE); key = (st_data_t)sock; st_delete(socklist, &key, NULL); sock = (SOCKET)key; _close(fd); errno = save_errno; if (closesocket(sock) == SOCKET_ERROR) { errno = map_errno(WSAGetLastError()); return -1; } return 0; } #undef read size_t rb_w32_read(int fd, void *buf, size_t size) { SOCKET sock = TO_SOCKET(fd); DWORD read; DWORD wait; DWORD err; OVERLAPPED ol, *pol = NULL; if (is_socket(sock)) return rb_w32_recv(fd, buf, size, 0); // validate fd by using _get_osfhandle() because we cannot access _nhandle if (_get_osfhandle(fd) == -1) { return -1; } if (_osfile(fd) & FTEXT) { return _read(fd, buf, size); } MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fd)->lock))); if (!size || _osfile(fd) & FEOFLAG) { MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return 0; } /* if have cancel_io, use Overlapped I/O */ if (cancel_io) { memset(&ol, 0, sizeof(ol)); if (!(_osfile(fd) & (FDEV | FPIPE))) { LONG high = 0; DWORD low = SetFilePointer((HANDLE)_osfhnd(fd), 0, &high, FILE_CURRENT); #ifndef INVALID_SET_FILE_POINTER #define INVALID_SET_FILE_POINTER ((DWORD)-1) #endif if (low == INVALID_SET_FILE_POINTER) { errno = map_errno(GetLastError()); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } ol.Offset = low; ol.OffsetHigh = high; } ol.hEvent = CreateEvent(NULL, TRUE, TRUE, NULL); if (!ol.hEvent) { errno = map_errno(GetLastError()); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } pol = &ol; } if (!ReadFile((HANDLE)_osfhnd(fd), buf, size, &read, pol)) { err = GetLastError(); if (err != ERROR_IO_PENDING) { if (err == ERROR_ACCESS_DENIED) errno = EBADF; else if (err == ERROR_BROKEN_PIPE || err == ERROR_HANDLE_EOF) { MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return 0; } else errno = map_errno(err); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } if (pol) { wait = rb_w32_wait_events_blocking(&ol.hEvent, 1, INFINITE); if (wait != WAIT_OBJECT_0) { if (wait == WAIT_OBJECT_0 + 1) errno = EINTR; else errno = map_errno(GetLastError()); CloseHandle(ol.hEvent); cancel_io((HANDLE)_osfhnd(fd)); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } if (!GetOverlappedResult((HANDLE)_osfhnd(fd), &ol, &read, TRUE) && (err = GetLastError()) != ERROR_HANDLE_EOF) { int ret = 0; if (err != ERROR_BROKEN_PIPE) { errno = map_errno(err); ret = -1; } CloseHandle(ol.hEvent); cancel_io((HANDLE)_osfhnd(fd)); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return ret; } } } if (pol) { CloseHandle(ol.hEvent); if (!(_osfile(fd) & (FDEV | FPIPE))) { LONG high = ol.OffsetHigh; DWORD low = ol.Offset + read; if (low < ol.Offset) ++high; SetFilePointer((HANDLE)_osfhnd(fd), low, &high, FILE_BEGIN); } } MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return read; } #undef write size_t rb_w32_write(int fd, const void *buf, size_t size) { SOCKET sock = TO_SOCKET(fd); DWORD written; DWORD wait; DWORD err; size_t len; size_t ret; OVERLAPPED ol, *pol = NULL; if (is_socket(sock)) return rb_w32_send(fd, buf, size, 0); // validate fd by using _get_osfhandle() because we cannot access _nhandle if (_get_osfhandle(fd) == -1) { return -1; } if (_osfile(fd) & FTEXT) { return _write(fd, buf, size); } MTHREAD_ONLY(EnterCriticalSection(&(_pioinfo(fd)->lock))); if (!size || _osfile(fd) & FEOFLAG) { MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return 0; } ret = 0; retry: /* get rid of console writing bug */ len = (_osfile(fd) & FDEV) ? min(32 * 1024, size) : size; size -= len; /* if have cancel_io, use Overlapped I/O */ if (cancel_io) { memset(&ol, 0, sizeof(ol)); if (!(_osfile(fd) & (FDEV | FPIPE))) { LONG high = 0; DWORD method = _osfile(fd) & FAPPEND ? FILE_END : FILE_CURRENT; DWORD low = SetFilePointer((HANDLE)_osfhnd(fd), 0, &high, method); #ifndef INVALID_SET_FILE_POINTER #define INVALID_SET_FILE_POINTER ((DWORD)-1) #endif if (low == INVALID_SET_FILE_POINTER) { errno = map_errno(GetLastError()); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } ol.Offset = low; ol.OffsetHigh = high; } ol.hEvent = CreateEvent(NULL, TRUE, TRUE, NULL); if (!ol.hEvent) { errno = map_errno(GetLastError()); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } pol = &ol; } if (!WriteFile((HANDLE)_osfhnd(fd), buf, len, &written, pol)) { err = GetLastError(); if (err != ERROR_IO_PENDING) { if (err == ERROR_ACCESS_DENIED) errno = EBADF; else errno = map_errno(err); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } if (pol) { wait = rb_w32_wait_events_blocking(&ol.hEvent, 1, INFINITE); if (wait != WAIT_OBJECT_0) { if (wait == WAIT_OBJECT_0 + 1) errno = EINTR; else errno = map_errno(GetLastError()); CloseHandle(ol.hEvent); cancel_io((HANDLE)_osfhnd(fd)); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } if (!GetOverlappedResult((HANDLE)_osfhnd(fd), &ol, &written, TRUE)) { errno = map_errno(err); CloseHandle(ol.hEvent); cancel_io((HANDLE)_osfhnd(fd)); MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return -1; } } } if (pol) { CloseHandle(ol.hEvent); if (!(_osfile(fd) & (FDEV | FPIPE))) { LONG high = ol.OffsetHigh; DWORD low = ol.Offset + written; if (low < ol.Offset) ++high; SetFilePointer((HANDLE)_osfhnd(fd), low, &high, FILE_BEGIN); } } ret += written; if (written == len) { buf = (const char *)buf + len; if (size > 0) goto retry; } MTHREAD_ONLY(LeaveCriticalSection(&_pioinfo(fd)->lock)); return ret; } static int unixtime_to_filetime(time_t time, FILETIME *ft) { struct tm *tm; SYSTEMTIME st; FILETIME lt; tm = localtime(&time); st.wYear = tm->tm_year + 1900; st.wMonth = tm->tm_mon + 1; st.wDayOfWeek = tm->tm_wday; st.wDay = tm->tm_mday; st.wHour = tm->tm_hour; st.wMinute = tm->tm_min; st.wSecond = tm->tm_sec; st.wMilliseconds = 0; if (!SystemTimeToFileTime(&st, <) || !LocalFileTimeToFileTime(<, ft)) { errno = map_errno(GetLastError()); return -1; } return 0; } int rb_w32_utime(const char *path, const struct utimbuf *times) { HANDLE hFile; FILETIME atime, mtime; struct stati64 stat; int ret = 0; if (rb_w32_stati64(path, &stat)) { return -1; } if (times) { if (unixtime_to_filetime(times->actime, &atime)) { return -1; } if (unixtime_to_filetime(times->modtime, &mtime)) { return -1; } } else { GetSystemTimeAsFileTime(&atime); mtime = atime; } RUBY_CRITICAL({ const DWORD attr = GetFileAttributes(path); if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) SetFileAttributes(path, attr & ~FILE_ATTRIBUTE_READONLY); hFile = CreateFile(path, GENERIC_WRITE, 0, 0, OPEN_EXISTING, IsWin95() ? 0 : FILE_FLAG_BACKUP_SEMANTICS, 0); if (hFile == INVALID_HANDLE_VALUE) { errno = map_errno(GetLastError()); ret = -1; } else { if (!SetFileTime(hFile, NULL, &atime, &mtime)) { errno = map_errno(GetLastError()); ret = -1; } CloseHandle(hFile); } if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) SetFileAttributes(path, attr); }); return ret; } int rb_w32_mkdir(const char *path, int mode) { int ret = -1; RUBY_CRITICAL(do { if (CreateDirectory(path, NULL) == FALSE) { errno = map_errno(GetLastError()); break; } if (chmod(path, mode) == -1) { RemoveDirectory(path); break; } ret = 0; } while (0)); return ret; } int rb_w32_rmdir(const char *path) { int ret = 0; RUBY_CRITICAL({ const DWORD attr = GetFileAttributes(path); if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) { SetFileAttributes(path, attr & ~FILE_ATTRIBUTE_READONLY); } if (RemoveDirectory(path) == FALSE) { errno = map_errno(GetLastError()); ret = -1; if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) { SetFileAttributes(path, attr); } } }); return ret; } int rb_w32_unlink(const char *path) { int ret = 0; RUBY_CRITICAL({ const DWORD attr = GetFileAttributes(path); if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) { SetFileAttributes(path, attr & ~FILE_ATTRIBUTE_READONLY); } if (DeleteFile(path) == FALSE) { errno = map_errno(GetLastError()); ret = -1; if (attr != (DWORD)-1 && (attr & FILE_ATTRIBUTE_READONLY)) { SetFileAttributes(path, attr); } } }); return ret; } #if !defined(__BORLANDC__) int rb_w32_isatty(int fd) { // validate fd by using _get_osfhandle() because we cannot access _nhandle if (_get_osfhandle(fd) == -1) { return 0; } if (!(_osfile(fd) & FDEV)) { errno = ENOTTY; return 0; } return 1; } #endif // // Fix bcc32's stdio bug // #ifdef __BORLANDC__ static int too_many_files(void) { FILE *f; for (f = _streams; f < _streams + _nfile; f++) { if (f->fd < 0) return 0; } return 1; } #undef fopen FILE * rb_w32_fopen(const char *path, const char *mode) { FILE *f = (errno = 0, fopen(path, mode)); if (f == NULL && errno == 0) { if (too_many_files()) errno = EMFILE; } return f; } FILE * rb_w32_fdopen(int handle, const char *type) { FILE *f = (errno = 0, _fdopen(handle, (char *)type)); if (f == NULL && errno == 0) { if (handle < 0) errno = EBADF; else if (too_many_files()) errno = EMFILE; } return f; } FILE * rb_w32_fsopen(const char *path, const char *mode, int shflags) { FILE *f = (errno = 0, _fsopen(path, mode, shflags)); if (f == NULL && errno == 0) { if (too_many_files()) errno = EMFILE; } return f; } #endif #if defined(_MSC_VER) && RT_VER <= 60 extern long _ftol(double); long _ftol2(double d) { return _ftol(d); } long _ftol2_sse(double d) { return _ftol(d); } #endif #ifndef signbit int signbit(double x) { int *ip = (int *)(&x + 1) - 1; return *ip < 0; } #endif