#include "../git-compat-util.h" #include "win32.h" #include #include "../strbuf.h" #include "../run-command.h" static const int delay[] = { 0, 1, 10, 20, 40 }; int err_win_to_posix(DWORD winerr) { int error = ENOSYS; switch(winerr) { case ERROR_ACCESS_DENIED: error = EACCES; break; case ERROR_ACCOUNT_DISABLED: error = EACCES; break; case ERROR_ACCOUNT_RESTRICTION: error = EACCES; break; case ERROR_ALREADY_ASSIGNED: error = EBUSY; break; case ERROR_ALREADY_EXISTS: error = EEXIST; break; case ERROR_ARITHMETIC_OVERFLOW: error = ERANGE; break; case ERROR_BAD_COMMAND: error = EIO; break; case ERROR_BAD_DEVICE: error = ENODEV; break; case ERROR_BAD_DRIVER_LEVEL: error = ENXIO; break; case ERROR_BAD_EXE_FORMAT: error = ENOEXEC; break; case ERROR_BAD_FORMAT: error = ENOEXEC; break; case ERROR_BAD_LENGTH: error = EINVAL; break; case ERROR_BAD_PATHNAME: error = ENOENT; break; case ERROR_BAD_PIPE: error = EPIPE; break; case ERROR_BAD_UNIT: error = ENODEV; break; case ERROR_BAD_USERNAME: error = EINVAL; break; case ERROR_BROKEN_PIPE: error = EPIPE; break; case ERROR_BUFFER_OVERFLOW: error = ENAMETOOLONG; break; case ERROR_BUSY: error = EBUSY; break; case ERROR_BUSY_DRIVE: error = EBUSY; break; case ERROR_CALL_NOT_IMPLEMENTED: error = ENOSYS; break; case ERROR_CANNOT_MAKE: error = EACCES; break; case ERROR_CANTOPEN: error = EIO; break; case ERROR_CANTREAD: error = EIO; break; case ERROR_CANTWRITE: error = EIO; break; case ERROR_CRC: error = EIO; break; case ERROR_CURRENT_DIRECTORY: error = EACCES; break; case ERROR_DEVICE_IN_USE: error = EBUSY; break; case ERROR_DEV_NOT_EXIST: error = ENODEV; break; case ERROR_DIRECTORY: error = EINVAL; break; case ERROR_DIR_NOT_EMPTY: error = ENOTEMPTY; break; case ERROR_DISK_CHANGE: error = EIO; break; case ERROR_DISK_FULL: error = ENOSPC; break; case ERROR_DRIVE_LOCKED: error = EBUSY; break; case ERROR_ENVVAR_NOT_FOUND: error = EINVAL; break; case ERROR_EXE_MARKED_INVALID: error = ENOEXEC; break; case ERROR_FILENAME_EXCED_RANGE: error = ENAMETOOLONG; break; case ERROR_FILE_EXISTS: error = EEXIST; break; case ERROR_FILE_INVALID: error = ENODEV; break; case ERROR_FILE_NOT_FOUND: error = ENOENT; break; case ERROR_GEN_FAILURE: error = EIO; break; case ERROR_HANDLE_DISK_FULL: error = ENOSPC; break; case ERROR_INSUFFICIENT_BUFFER: error = ENOMEM; break; case ERROR_INVALID_ACCESS: error = EACCES; break; case ERROR_INVALID_ADDRESS: error = EFAULT; break; case ERROR_INVALID_BLOCK: error = EFAULT; break; case ERROR_INVALID_DATA: error = EINVAL; break; case ERROR_INVALID_DRIVE: error = ENODEV; break; case ERROR_INVALID_EXE_SIGNATURE: error = ENOEXEC; break; case ERROR_INVALID_FLAGS: error = EINVAL; break; case ERROR_INVALID_FUNCTION: error = ENOSYS; break; case ERROR_INVALID_HANDLE: error = EBADF; break; case ERROR_INVALID_LOGON_HOURS: error = EACCES; break; case ERROR_INVALID_NAME: error = EINVAL; break; case ERROR_INVALID_OWNER: error = EINVAL; break; case ERROR_INVALID_PARAMETER: error = EINVAL; break; case ERROR_INVALID_PASSWORD: error = EPERM; break; case ERROR_INVALID_PRIMARY_GROUP: error = EINVAL; break; case ERROR_INVALID_SIGNAL_NUMBER: error = EINVAL; break; case ERROR_INVALID_TARGET_HANDLE: error = EIO; break; case ERROR_INVALID_WORKSTATION: error = EACCES; break; case ERROR_IO_DEVICE: error = EIO; break; case ERROR_IO_INCOMPLETE: error = EINTR; break; case ERROR_LOCKED: error = EBUSY; break; case ERROR_LOCK_VIOLATION: error = EACCES; break; case ERROR_LOGON_FAILURE: error = EACCES; break; case ERROR_MAPPED_ALIGNMENT: error = EINVAL; break; case ERROR_META_EXPANSION_TOO_LONG: error = E2BIG; break; case ERROR_MORE_DATA: error = EPIPE; break; case ERROR_NEGATIVE_SEEK: error = ESPIPE; break; case ERROR_NOACCESS: error = EFAULT; break; case ERROR_NONE_MAPPED: error = EINVAL; break; case ERROR_NOT_ENOUGH_MEMORY: error = ENOMEM; break; case ERROR_NOT_READY: error = EAGAIN; break; case ERROR_NOT_SAME_DEVICE: error = EXDEV; break; case ERROR_NO_DATA: error = EPIPE; break; case ERROR_NO_MORE_SEARCH_HANDLES: error = EIO; break; case ERROR_NO_PROC_SLOTS: error = EAGAIN; break; case ERROR_NO_SUCH_PRIVILEGE: error = EACCES; break; case ERROR_OPEN_FAILED: error = EIO; break; case ERROR_OPEN_FILES: error = EBUSY; break; case ERROR_OPERATION_ABORTED: error = EINTR; break; case ERROR_OUTOFMEMORY: error = ENOMEM; break; case ERROR_PASSWORD_EXPIRED: error = EACCES; break; case ERROR_PATH_BUSY: error = EBUSY; break; case ERROR_PATH_NOT_FOUND: error = ENOENT; break; case ERROR_PIPE_BUSY: error = EBUSY; break; case ERROR_PIPE_CONNECTED: error = EPIPE; break; case ERROR_PIPE_LISTENING: error = EPIPE; break; case ERROR_PIPE_NOT_CONNECTED: error = EPIPE; break; case ERROR_PRIVILEGE_NOT_HELD: error = EACCES; break; case ERROR_READ_FAULT: error = EIO; break; case ERROR_SEEK: error = EIO; break; case ERROR_SEEK_ON_DEVICE: error = ESPIPE; break; case ERROR_SHARING_BUFFER_EXCEEDED: error = ENFILE; break; case ERROR_SHARING_VIOLATION: error = EACCES; break; case ERROR_STACK_OVERFLOW: error = ENOMEM; break; case ERROR_SWAPERROR: error = ENOENT; break; case ERROR_TOO_MANY_MODULES: error = EMFILE; break; case ERROR_TOO_MANY_OPEN_FILES: error = EMFILE; break; case ERROR_UNRECOGNIZED_MEDIA: error = ENXIO; break; case ERROR_UNRECOGNIZED_VOLUME: error = ENODEV; break; case ERROR_WAIT_NO_CHILDREN: error = ECHILD; break; case ERROR_WRITE_FAULT: error = EIO; break; case ERROR_WRITE_PROTECT: error = EROFS; break; } return error; } static inline int is_file_in_use_error(DWORD errcode) { switch (errcode) { case ERROR_SHARING_VIOLATION: case ERROR_ACCESS_DENIED: return 1; } return 0; } static int read_yes_no_answer(void) { char answer[1024]; if (fgets(answer, sizeof(answer), stdin)) { size_t answer_len = strlen(answer); int got_full_line = 0, c; /* remove the newline */ if (answer_len >= 2 && answer[answer_len-2] == '\r') { answer[answer_len-2] = '\0'; got_full_line = 1; } else if (answer_len >= 1 && answer[answer_len-1] == '\n') { answer[answer_len-1] = '\0'; got_full_line = 1; } /* flush the buffer in case we did not get the full line */ if (!got_full_line) while ((c = getchar()) != EOF && c != '\n') ; } else /* we could not read, return the * default answer which is no */ return 0; if (tolower(answer[0]) == 'y' && !answer[1]) return 1; if (!strncasecmp(answer, "yes", sizeof(answer))) return 1; if (tolower(answer[0]) == 'n' && !answer[1]) return 0; if (!strncasecmp(answer, "no", sizeof(answer))) return 0; /* did not find an answer we understand */ return -1; } static int ask_yes_no_if_possible(const char *format, ...) { char question[4096]; const char *retry_hook[] = { NULL, NULL, NULL }; va_list args; va_start(args, format); vsnprintf(question, sizeof(question), format, args); va_end(args); if ((retry_hook[0] = mingw_getenv("GIT_ASK_YESNO"))) { retry_hook[1] = question; return !run_command_v_opt(retry_hook, 0); } if (!isatty(_fileno(stdin)) || !isatty(_fileno(stderr))) return 0; while (1) { int answer; fprintf(stderr, "%s (y/n) ", question); if ((answer = read_yes_no_answer()) >= 0) return answer; fprintf(stderr, "Sorry, I did not understand your answer. " "Please type 'y' or 'n'\n"); } } #undef unlink int mingw_unlink(const char *pathname) { int ret, tries = 0; /* read-only files cannot be removed */ chmod(pathname, 0666); while ((ret = unlink(pathname)) == -1 && tries < ARRAY_SIZE(delay)) { if (!is_file_in_use_error(GetLastError())) break; /* * We assume that some other process had the source or * destination file open at the wrong moment and retry. * In order to give the other process a higher chance to * complete its operation, we give up our time slice now. * If we have to retry again, we do sleep a bit. */ Sleep(delay[tries]); tries++; } while (ret == -1 && is_file_in_use_error(GetLastError()) && ask_yes_no_if_possible("Unlink of file '%s' failed. " "Should I try again?", pathname)) ret = unlink(pathname); return ret; } static int is_dir_empty(const char *path) { struct strbuf buf = STRBUF_INIT; WIN32_FIND_DATAA findbuf; HANDLE handle; strbuf_addf(&buf, "%s\\*", path); handle = FindFirstFileA(buf.buf, &findbuf); if (handle == INVALID_HANDLE_VALUE) { strbuf_release(&buf); return GetLastError() == ERROR_NO_MORE_FILES; } while (!strcmp(findbuf.cFileName, ".") || !strcmp(findbuf.cFileName, "..")) if (!FindNextFile(handle, &findbuf)) { strbuf_release(&buf); return GetLastError() == ERROR_NO_MORE_FILES; } FindClose(handle); strbuf_release(&buf); return 0; } #undef rmdir int mingw_rmdir(const char *pathname) { int ret, tries = 0; while ((ret = rmdir(pathname)) == -1 && tries < ARRAY_SIZE(delay)) { if (!is_file_in_use_error(GetLastError())) errno = err_win_to_posix(GetLastError()); if (errno != EACCES) break; if (!is_dir_empty(pathname)) { errno = ENOTEMPTY; break; } /* * We assume that some other process had the source or * destination file open at the wrong moment and retry. * In order to give the other process a higher chance to * complete its operation, we give up our time slice now. * If we have to retry again, we do sleep a bit. */ Sleep(delay[tries]); tries++; } while (ret == -1 && errno == EACCES && is_file_in_use_error(GetLastError()) && ask_yes_no_if_possible("Deletion of directory '%s' failed. " "Should I try again?", pathname)) ret = rmdir(pathname); return ret; } #undef open int mingw_open (const char *filename, int oflags, ...) { va_list args; unsigned mode; int fd; va_start(args, oflags); mode = va_arg(args, int); va_end(args); if (filename && !strcmp(filename, "/dev/null")) filename = "nul"; fd = open(filename, oflags, mode); if (fd < 0 && (oflags & O_CREAT) && errno == EACCES) { DWORD attrs = GetFileAttributes(filename); if (attrs != INVALID_FILE_ATTRIBUTES && (attrs & FILE_ATTRIBUTE_DIRECTORY)) errno = EISDIR; } return fd; } #undef write ssize_t mingw_write(int fd, const void *buf, size_t count) { /* * While write() calls to a file on a local disk are translated * into WriteFile() calls with a maximum size of 64KB on Windows * XP and 256KB on Vista, no such cap is placed on writes to * files over the network on Windows XP. Unfortunately, there * seems to be a limit of 32MB-28KB on X64 and 64MB-32KB on x86; * bigger writes fail on Windows XP. * So we cap to a nice 31MB here to avoid write failures over * the net without changing the number of WriteFile() calls in * the local case. */ return write(fd, buf, min(count, 31 * 1024 * 1024)); } static BOOL WINAPI ctrl_ignore(DWORD type) { return TRUE; } #undef fgetc int mingw_fgetc(FILE *stream) { int ch; if (!isatty(_fileno(stream))) return fgetc(stream); SetConsoleCtrlHandler(ctrl_ignore, TRUE); while (1) { ch = fgetc(stream); if (ch != EOF || GetLastError() != ERROR_OPERATION_ABORTED) break; /* Ctrl+C was pressed, simulate SIGINT and retry */ mingw_raise(SIGINT); } SetConsoleCtrlHandler(ctrl_ignore, FALSE); return ch; } #undef fopen FILE *mingw_fopen (const char *filename, const char *otype) { if (filename && !strcmp(filename, "/dev/null")) filename = "nul"; return fopen(filename, otype); } #undef freopen FILE *mingw_freopen (const char *filename, const char *otype, FILE *stream) { if (filename && !strcmp(filename, "/dev/null")) filename = "nul"; return freopen(filename, otype, stream); } #undef fflush int mingw_fflush(FILE *stream) { int ret = fflush(stream); /* * write() is used behind the scenes of stdio output functions. * Since git code does not check for errors after each stdio write * operation, it can happen that write() is called by a later * stdio function even if an earlier write() call failed. In the * case of a pipe whose readable end was closed, only the first * call to write() reports EPIPE on Windows. Subsequent write() * calls report EINVAL. It is impossible to notice whether this * fflush invocation triggered such a case, therefore, we have to * catch all EINVAL errors whole-sale. */ if (ret && errno == EINVAL) errno = EPIPE; return ret; } /* * The unit of FILETIME is 100-nanoseconds since January 1, 1601, UTC. * Returns the 100-nanoseconds ("hekto nanoseconds") since the epoch. */ static inline long long filetime_to_hnsec(const FILETIME *ft) { long long winTime = ((long long)ft->dwHighDateTime << 32) + ft->dwLowDateTime; /* Windows to Unix Epoch conversion */ return winTime - 116444736000000000LL; } static inline time_t filetime_to_time_t(const FILETIME *ft) { return (time_t)(filetime_to_hnsec(ft) / 10000000); } /* We keep the do_lstat code in a separate function to avoid recursion. * When a path ends with a slash, the stat will fail with ENOENT. In * this case, we strip the trailing slashes and stat again. * * If follow is true then act like stat() and report on the link * target. Otherwise report on the link itself. */ static int do_lstat(int follow, const char *file_name, struct stat *buf) { int err; WIN32_FILE_ATTRIBUTE_DATA fdata; if (!(err = get_file_attr(file_name, &fdata))) { buf->st_ino = 0; buf->st_gid = 0; buf->st_uid = 0; buf->st_nlink = 1; buf->st_mode = file_attr_to_st_mode(fdata.dwFileAttributes); buf->st_size = fdata.nFileSizeLow | (((off_t)fdata.nFileSizeHigh)<<32); buf->st_dev = buf->st_rdev = 0; /* not used by Git */ buf->st_atime = filetime_to_time_t(&(fdata.ftLastAccessTime)); buf->st_mtime = filetime_to_time_t(&(fdata.ftLastWriteTime)); buf->st_ctime = filetime_to_time_t(&(fdata.ftCreationTime)); if (fdata.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) { WIN32_FIND_DATAA findbuf; HANDLE handle = FindFirstFileA(file_name, &findbuf); if (handle != INVALID_HANDLE_VALUE) { if ((findbuf.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) && (findbuf.dwReserved0 == IO_REPARSE_TAG_SYMLINK)) { if (follow) { char buffer[MAXIMUM_REPARSE_DATA_BUFFER_SIZE]; buf->st_size = readlink(file_name, buffer, MAXIMUM_REPARSE_DATA_BUFFER_SIZE); } else { buf->st_mode = S_IFLNK; } buf->st_mode |= S_IREAD; if (!(findbuf.dwFileAttributes & FILE_ATTRIBUTE_READONLY)) buf->st_mode |= S_IWRITE; } FindClose(handle); } } return 0; } errno = err; return -1; } /* We provide our own lstat/fstat functions, since the provided * lstat/fstat functions are so slow. These stat functions are * tailored for Git's usage (read: fast), and are not meant to be * complete. Note that Git stat()s are redirected to mingw_lstat() * too, since Windows doesn't really handle symlinks that well. */ static int do_stat_internal(int follow, const char *file_name, struct stat *buf) { int namelen; static char alt_name[PATH_MAX]; if (!do_lstat(follow, file_name, buf)) return 0; /* if file_name ended in a '/', Windows returned ENOENT; * try again without trailing slashes */ if (errno != ENOENT) return -1; namelen = strlen(file_name); if (namelen && file_name[namelen-1] != '/') return -1; while (namelen && file_name[namelen-1] == '/') --namelen; if (!namelen || namelen >= PATH_MAX) return -1; memcpy(alt_name, file_name, namelen); alt_name[namelen] = 0; return do_lstat(follow, alt_name, buf); } int mingw_lstat(const char *file_name, struct stat *buf) { return do_stat_internal(0, file_name, buf); } int mingw_stat(const char *file_name, struct stat *buf) { return do_stat_internal(1, file_name, buf); } #undef fstat int mingw_fstat(int fd, struct stat *buf) { HANDLE fh = (HANDLE)_get_osfhandle(fd); BY_HANDLE_FILE_INFORMATION fdata; if (fh == INVALID_HANDLE_VALUE) { errno = EBADF; return -1; } /* direct non-file handles to MS's fstat() */ if (GetFileType(fh) != FILE_TYPE_DISK) return _fstati64(fd, buf); if (GetFileInformationByHandle(fh, &fdata)) { buf->st_ino = 0; buf->st_gid = 0; buf->st_uid = 0; buf->st_nlink = 1; buf->st_mode = file_attr_to_st_mode(fdata.dwFileAttributes); buf->st_size = fdata.nFileSizeLow | (((off_t)fdata.nFileSizeHigh)<<32); buf->st_dev = buf->st_rdev = 0; /* not used by Git */ buf->st_atime = filetime_to_time_t(&(fdata.ftLastAccessTime)); buf->st_mtime = filetime_to_time_t(&(fdata.ftLastWriteTime)); buf->st_ctime = filetime_to_time_t(&(fdata.ftCreationTime)); return 0; } errno = EBADF; return -1; } static inline void time_t_to_filetime(time_t t, FILETIME *ft) { long long winTime = t * 10000000LL + 116444736000000000LL; ft->dwLowDateTime = winTime; ft->dwHighDateTime = winTime >> 32; } int mingw_utime (const char *file_name, const struct utimbuf *times) { FILETIME mft, aft; int fh, rc; /* must have write permission */ DWORD attrs = GetFileAttributes(file_name); if (attrs != INVALID_FILE_ATTRIBUTES && (attrs & FILE_ATTRIBUTE_READONLY)) { /* ignore errors here; open() will report them */ SetFileAttributes(file_name, attrs & ~FILE_ATTRIBUTE_READONLY); } if ((fh = open(file_name, O_RDWR | O_BINARY)) < 0) { rc = -1; goto revert_attrs; } if (times) { time_t_to_filetime(times->modtime, &mft); time_t_to_filetime(times->actime, &aft); } else { GetSystemTimeAsFileTime(&mft); aft = mft; } if (!SetFileTime((HANDLE)_get_osfhandle(fh), NULL, &aft, &mft)) { errno = EINVAL; rc = -1; } else rc = 0; close(fh); revert_attrs: if (attrs != INVALID_FILE_ATTRIBUTES && (attrs & FILE_ATTRIBUTE_READONLY)) { /* ignore errors again */ SetFileAttributes(file_name, attrs); } return rc; } unsigned int sleep (unsigned int seconds) { Sleep(seconds*1000); return 0; } int mkstemp(char *template) { char *filename = mktemp(template); if (filename == NULL) return -1; return open(filename, O_RDWR | O_CREAT, 0600); } int gettimeofday(struct timeval *tv, void *tz) { FILETIME ft; long long hnsec; GetSystemTimeAsFileTime(&ft); hnsec = filetime_to_hnsec(&ft); tv->tv_sec = hnsec / 10000000; tv->tv_usec = (hnsec % 10000000) / 10; return 0; } int pipe(int filedes[2]) { HANDLE h[2]; /* this creates non-inheritable handles */ if (!CreatePipe(&h[0], &h[1], NULL, 8192)) { errno = err_win_to_posix(GetLastError()); return -1; } filedes[0] = _open_osfhandle((int)h[0], O_NOINHERIT); if (filedes[0] < 0) { CloseHandle(h[0]); CloseHandle(h[1]); return -1; } filedes[1] = _open_osfhandle((int)h[1], O_NOINHERIT); if (filedes[0] < 0) { close(filedes[0]); CloseHandle(h[1]); return -1; } return 0; } struct tm *gmtime_r(const time_t *timep, struct tm *result) { /* gmtime() in MSVCRT.DLL is thread-safe, but not reentrant */ memcpy(result, gmtime(timep), sizeof(struct tm)); return result; } struct tm *localtime_r(const time_t *timep, struct tm *result) { /* localtime() in MSVCRT.DLL is thread-safe, but not reentrant */ memcpy(result, localtime(timep), sizeof(struct tm)); return result; } #undef getcwd char *mingw_getcwd(char *pointer, int len) { int i; char *ret = getcwd(pointer, len); if (!ret) return ret; for (i = 0; pointer[i]; i++) if (pointer[i] == '\\') pointer[i] = '/'; return ret; } /* * See http://msdn2.microsoft.com/en-us/library/17w5ykft(vs.71).aspx * (Parsing C++ Command-Line Arguments) */ static const char *quote_arg(const char *arg) { /* count chars to quote */ int len = 0, n = 0; int force_quotes = 0; char *q, *d; const char *p = arg; if (!*p) force_quotes = 1; while (*p) { if (isspace(*p) || *p == '*' || *p == '?' || *p == '{' || *p == '\'') force_quotes = 1; else if (*p == '"') n++; else if (*p == '\\') { int count = 0; while (*p == '\\') { count++; p++; len++; } if (*p == '"') n += count*2 + 1; continue; } len++; p++; } if (!force_quotes && n == 0) return arg; /* insert \ where necessary */ d = q = xmalloc(len+n+3); *d++ = '"'; while (*arg) { if (*arg == '"') *d++ = '\\'; else if (*arg == '\\') { int count = 0; while (*arg == '\\') { count++; *d++ = *arg++; } if (*arg == '"') { while (count-- > 0) *d++ = '\\'; *d++ = '\\'; } } *d++ = *arg++; } *d++ = '"'; *d++ = 0; return q; } static const char *parse_interpreter(const char *cmd) { static char buf[100]; char *p, *opt; int n, fd; /* don't even try a .exe */ n = strlen(cmd); if (n >= 4 && !strcasecmp(cmd+n-4, ".exe")) return NULL; fd = open(cmd, O_RDONLY); if (fd < 0) return NULL; n = read(fd, buf, sizeof(buf)-1); close(fd); if (n < 4) /* at least '#!/x' and not error */ return NULL; if (buf[0] != '#' || buf[1] != '!') return NULL; buf[n] = '\0'; p = buf + strcspn(buf, "\r\n"); if (!*p) return NULL; *p = '\0'; if (!(p = strrchr(buf+2, '/')) && !(p = strrchr(buf+2, '\\'))) return NULL; /* strip options */ if ((opt = strchr(p+1, ' '))) *opt = '\0'; return p+1; } /* * Splits the PATH into parts. */ static char **get_path_split(void) { char *p, **path, *envpath = mingw_getenv("PATH"); int i, n = 0; if (!envpath || !*envpath) return NULL; envpath = xstrdup(envpath); p = envpath; while (p) { char *dir = p; p = strchr(p, ';'); if (p) *p++ = '\0'; if (*dir) { /* not earlier, catches series of ; */ ++n; } } if (!n) return NULL; path = xmalloc((n+1)*sizeof(char *)); p = envpath; i = 0; do { if (*p) path[i++] = xstrdup(p); p = p+strlen(p)+1; } while (i < n); path[i] = NULL; free(envpath); return path; } static void free_path_split(char **path) { char **p = path; if (!path) return; while (*p) free(*p++); free(path); } /* * exe_only means that we only want to detect .exe files, but not scripts * (which do not have an extension) */ static char *lookup_prog(const char *dir, const char *cmd, int isexe, int exe_only) { char path[MAX_PATH]; snprintf(path, sizeof(path), "%s/%s.exe", dir, cmd); if (!isexe && access(path, F_OK) == 0) return xstrdup(path); path[strlen(path)-4] = '\0'; if ((!exe_only || isexe) && access(path, F_OK) == 0) if (!(GetFileAttributes(path) & FILE_ATTRIBUTE_DIRECTORY)) return xstrdup(path); return NULL; } /* * Determines the absolute path of cmd using the split path in path. * If cmd contains a slash or backslash, no lookup is performed. */ static char *path_lookup(const char *cmd, char **path, int exe_only) { char *prog = NULL; int len = strlen(cmd); int isexe = len >= 4 && !strcasecmp(cmd+len-4, ".exe"); if (strchr(cmd, '/') || strchr(cmd, '\\')) prog = xstrdup(cmd); while (!prog && *path) prog = lookup_prog(*path++, cmd, isexe, exe_only); return prog; } static int env_compare(const void *a, const void *b) { char *const *ea = a; char *const *eb = b; return strcasecmp(*ea, *eb); } struct pinfo_t { struct pinfo_t *next; pid_t pid; HANDLE proc; } pinfo_t; struct pinfo_t *pinfo = NULL; CRITICAL_SECTION pinfo_cs; static pid_t mingw_spawnve_fd(const char *cmd, const char **argv, char **env, const char *dir, int prepend_cmd, int fhin, int fhout, int fherr) { STARTUPINFO si; PROCESS_INFORMATION pi; struct strbuf envblk, args; unsigned flags; BOOL ret; /* Determine whether or not we are associated to a console */ HANDLE cons = CreateFile("CONOUT$", GENERIC_WRITE, FILE_SHARE_WRITE, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL); if (cons == INVALID_HANDLE_VALUE) { /* There is no console associated with this process. * Since the child is a console process, Windows * would normally create a console window. But * since we'll be redirecting std streams, we do * not need the console. * It is necessary to use DETACHED_PROCESS * instead of CREATE_NO_WINDOW to make ssh * recognize that it has no console. */ flags = DETACHED_PROCESS; } else { /* There is already a console. If we specified * DETACHED_PROCESS here, too, Windows would * disassociate the child from the console. * The same is true for CREATE_NO_WINDOW. * Go figure! */ flags = 0; CloseHandle(cons); } memset(&si, 0, sizeof(si)); si.cb = sizeof(si); si.dwFlags = STARTF_USESTDHANDLES; si.hStdInput = (HANDLE) _get_osfhandle(fhin); si.hStdOutput = (HANDLE) _get_osfhandle(fhout); si.hStdError = (HANDLE) _get_osfhandle(fherr); /* concatenate argv, quoting args as we go */ strbuf_init(&args, 0); if (prepend_cmd) { char *quoted = (char *)quote_arg(cmd); strbuf_addstr(&args, quoted); if (quoted != cmd) free(quoted); } for (; *argv; argv++) { char *quoted = (char *)quote_arg(*argv); if (*args.buf) strbuf_addch(&args, ' '); strbuf_addstr(&args, quoted); if (quoted != *argv) free(quoted); } if (env) { int count = 0; char **e, **sorted_env; for (e = env; *e; e++) count++; /* environment must be sorted */ sorted_env = xmalloc(sizeof(*sorted_env) * (count + 1)); memcpy(sorted_env, env, sizeof(*sorted_env) * (count + 1)); qsort(sorted_env, count, sizeof(*sorted_env), env_compare); strbuf_init(&envblk, 0); for (e = sorted_env; *e; e++) { strbuf_addstr(&envblk, *e); strbuf_addch(&envblk, '\0'); } free(sorted_env); } memset(&pi, 0, sizeof(pi)); ret = CreateProcess(cmd, args.buf, NULL, NULL, TRUE, flags, env ? envblk.buf : NULL, dir, &si, &pi); if (env) strbuf_release(&envblk); strbuf_release(&args); if (!ret) { errno = ENOENT; return -1; } CloseHandle(pi.hThread); /* * The process ID is the human-readable identifier of the process * that we want to present in log and error messages. The handle * is not useful for this purpose. But we cannot close it, either, * because it is not possible to turn a process ID into a process * handle after the process terminated. * Keep the handle in a list for waitpid. */ EnterCriticalSection(&pinfo_cs); { struct pinfo_t *info = xmalloc(sizeof(struct pinfo_t)); info->pid = pi.dwProcessId; info->proc = pi.hProcess; info->next = pinfo; pinfo = info; } LeaveCriticalSection(&pinfo_cs); return (pid_t)pi.dwProcessId; } static pid_t mingw_spawnve(const char *cmd, const char **argv, char **env, int prepend_cmd) { return mingw_spawnve_fd(cmd, argv, env, NULL, prepend_cmd, 0, 1, 2); } pid_t mingw_spawnvpe(const char *cmd, const char **argv, char **env, const char *dir, int fhin, int fhout, int fherr) { pid_t pid; char **path = get_path_split(); char *prog = path_lookup(cmd, path, 0); if (!prog) { errno = ENOENT; pid = -1; } else { const char *interpr = parse_interpreter(prog); if (interpr) { const char *argv0 = argv[0]; char *iprog = path_lookup(interpr, path, 1); argv[0] = prog; if (!iprog) { errno = ENOENT; pid = -1; } else { pid = mingw_spawnve_fd(iprog, argv, env, dir, 1, fhin, fhout, fherr); free(iprog); } argv[0] = argv0; } else pid = mingw_spawnve_fd(prog, argv, env, dir, 0, fhin, fhout, fherr); free(prog); } free_path_split(path); return pid; } static int try_shell_exec(const char *cmd, char *const *argv, char **env) { const char *interpr = parse_interpreter(cmd); char **path; char *prog; int pid = 0; if (!interpr) return 0; path = get_path_split(); prog = path_lookup(interpr, path, 1); if (prog) { int argc = 0; const char **argv2; while (argv[argc]) argc++; argv2 = xmalloc(sizeof(*argv) * (argc+1)); argv2[0] = (char *)cmd; /* full path to the script file */ memcpy(&argv2[1], &argv[1], sizeof(*argv) * argc); pid = mingw_spawnve(prog, argv2, env, 1); if (pid >= 0) { int status; if (waitpid(pid, &status, 0) < 0) status = 255; exit(status); } pid = 1; /* indicate that we tried but failed */ free(prog); free(argv2); } free_path_split(path); return pid; } static void mingw_execve(const char *cmd, char *const *argv, char *const *env) { /* check if git_command is a shell script */ if (!try_shell_exec(cmd, argv, (char **)env)) { int pid, status; pid = mingw_spawnve(cmd, (const char **)argv, (char **)env, 0); if (pid < 0) return; if (waitpid(pid, &status, 0) < 0) status = 255; exit(status); } } int mingw_execvp(const char *cmd, char *const *argv) { char **path = get_path_split(); char *prog = path_lookup(cmd, path, 0); if (prog) { mingw_execve(prog, argv, environ); free(prog); } else errno = ENOENT; free_path_split(path); return -1; } int mingw_execv(const char *cmd, char *const *argv) { mingw_execve(cmd, argv, environ); return -1; } int mingw_kill(pid_t pid, int sig) { if (pid > 0 && sig == SIGTERM) { HANDLE h = OpenProcess(PROCESS_TERMINATE, FALSE, pid); if (TerminateProcess(h, -1)) { CloseHandle(h); return 0; } errno = err_win_to_posix(GetLastError()); CloseHandle(h); return -1; } else if (pid > 0 && sig == 0) { HANDLE h = OpenProcess(PROCESS_QUERY_INFORMATION, FALSE, pid); if (h) { CloseHandle(h); return 0; } } errno = EINVAL; return -1; } static char **copy_environ(void) { char **env; int i = 0; while (environ[i]) i++; env = xmalloc((i+1)*sizeof(*env)); for (i = 0; environ[i]; i++) env[i] = xstrdup(environ[i]); env[i] = NULL; return env; } void free_environ(char **env) { int i; for (i = 0; env[i]; i++) free(env[i]); free(env); } static int lookup_env(char **env, const char *name, size_t nmln) { int i; for (i = 0; env[i]; i++) { if (0 == strncmp(env[i], name, nmln) && '=' == env[i][nmln]) /* matches */ return i; } return -1; } /* * If name contains '=', then sets the variable, otherwise it unsets it */ static char **env_setenv(char **env, const char *name) { char *eq = strchrnul(name, '='); int i = lookup_env(env, name, eq-name); if (i < 0) { if (*eq) { for (i = 0; env[i]; i++) ; env = xrealloc(env, (i+2)*sizeof(*env)); env[i] = xstrdup(name); env[i+1] = NULL; } } else { free(env[i]); if (*eq) env[i] = xstrdup(name); else for (; env[i]; i++) env[i] = env[i+1]; } return env; } /* * Copies global environ and adjusts variables as specified by vars. */ char **make_augmented_environ(const char *const *vars) { char **env = copy_environ(); while (*vars) env = env_setenv(env, *vars++); return env; } #undef getenv /* * The system's getenv looks up the name in a case-insensitive manner. * This version tries a case-sensitive lookup and falls back to * case-insensitive if nothing was found. This is necessary because, * as a prominent example, CMD sets 'Path', but not 'PATH'. * Warning: not thread-safe. */ static char *getenv_cs(const char *name) { size_t len = strlen(name); int i = lookup_env(environ, name, len); if (i >= 0) return environ[i] + len + 1; /* skip past name and '=' */ return getenv(name); } char *mingw_getenv(const char *name) { char *result = getenv_cs(name); if (!result && !strcmp(name, "TMPDIR")) { /* on Windows it is TMP and TEMP */ result = getenv_cs("TMP"); if (!result) result = getenv_cs("TEMP"); } return result; } /* * Note, this isn't a complete replacement for getaddrinfo. It assumes * that service contains a numerical port, or that it is null. It * does a simple search using gethostbyname, and returns one IPv4 host * if one was found. */ static int WSAAPI getaddrinfo_stub(const char *node, const char *service, const struct addrinfo *hints, struct addrinfo **res) { struct hostent *h = NULL; struct addrinfo *ai; struct sockaddr_in *sin; if (node) { h = gethostbyname(node); if (!h) return WSAGetLastError(); } ai = xmalloc(sizeof(struct addrinfo)); *res = ai; ai->ai_flags = 0; ai->ai_family = AF_INET; ai->ai_socktype = hints ? hints->ai_socktype : 0; switch (ai->ai_socktype) { case SOCK_STREAM: ai->ai_protocol = IPPROTO_TCP; break; case SOCK_DGRAM: ai->ai_protocol = IPPROTO_UDP; break; default: ai->ai_protocol = 0; break; } ai->ai_addrlen = sizeof(struct sockaddr_in); if (hints && (hints->ai_flags & AI_CANONNAME)) ai->ai_canonname = h ? xstrdup(h->h_name) : NULL; else ai->ai_canonname = NULL; sin = xmalloc(ai->ai_addrlen); memset(sin, 0, ai->ai_addrlen); sin->sin_family = AF_INET; /* Note: getaddrinfo is supposed to allow service to be a string, * which should be looked up using getservbyname. This is * currently not implemented */ if (service) sin->sin_port = htons(atoi(service)); if (h) sin->sin_addr = *(struct in_addr *)h->h_addr; else if (hints && (hints->ai_flags & AI_PASSIVE)) sin->sin_addr.s_addr = INADDR_ANY; else sin->sin_addr.s_addr = INADDR_LOOPBACK; ai->ai_addr = (struct sockaddr *)sin; ai->ai_next = 0; return 0; } static void WSAAPI freeaddrinfo_stub(struct addrinfo *res) { free(res->ai_canonname); free(res->ai_addr); free(res); } static int WSAAPI getnameinfo_stub(const struct sockaddr *sa, socklen_t salen, char *host, DWORD hostlen, char *serv, DWORD servlen, int flags) { const struct sockaddr_in *sin = (const struct sockaddr_in *)sa; if (sa->sa_family != AF_INET) return EAI_FAMILY; if (!host && !serv) return EAI_NONAME; if (host && hostlen > 0) { struct hostent *ent = NULL; if (!(flags & NI_NUMERICHOST)) ent = gethostbyaddr((const char *)&sin->sin_addr, sizeof(sin->sin_addr), AF_INET); if (ent) snprintf(host, hostlen, "%s", ent->h_name); else if (flags & NI_NAMEREQD) return EAI_NONAME; else snprintf(host, hostlen, "%s", inet_ntoa(sin->sin_addr)); } if (serv && servlen > 0) { struct servent *ent = NULL; if (!(flags & NI_NUMERICSERV)) ent = getservbyport(sin->sin_port, flags & NI_DGRAM ? "udp" : "tcp"); if (ent) snprintf(serv, servlen, "%s", ent->s_name); else snprintf(serv, servlen, "%d", ntohs(sin->sin_port)); } return 0; } static HMODULE ipv6_dll = NULL; static void (WSAAPI *ipv6_freeaddrinfo)(struct addrinfo *res); static int (WSAAPI *ipv6_getaddrinfo)(const char *node, const char *service, const struct addrinfo *hints, struct addrinfo **res); static int (WSAAPI *ipv6_getnameinfo)(const struct sockaddr *sa, socklen_t salen, char *host, DWORD hostlen, char *serv, DWORD servlen, int flags); /* * gai_strerror is an inline function in the ws2tcpip.h header, so we * don't need to try to load that one dynamically. */ static void socket_cleanup(void) { WSACleanup(); if (ipv6_dll) FreeLibrary(ipv6_dll); ipv6_dll = NULL; ipv6_freeaddrinfo = freeaddrinfo_stub; ipv6_getaddrinfo = getaddrinfo_stub; ipv6_getnameinfo = getnameinfo_stub; } static void ensure_socket_initialization(void) { WSADATA wsa; static int initialized = 0; const char *libraries[] = { "ws2_32.dll", "wship6.dll", NULL }; const char **name; if (initialized) return; if (WSAStartup(MAKEWORD(2,2), &wsa)) die("unable to initialize winsock subsystem, error %d", WSAGetLastError()); for (name = libraries; *name; name++) { ipv6_dll = LoadLibrary(*name); if (!ipv6_dll) continue; ipv6_freeaddrinfo = (void (WSAAPI *)(struct addrinfo *)) GetProcAddress(ipv6_dll, "freeaddrinfo"); ipv6_getaddrinfo = (int (WSAAPI *)(const char *, const char *, const struct addrinfo *, struct addrinfo **)) GetProcAddress(ipv6_dll, "getaddrinfo"); ipv6_getnameinfo = (int (WSAAPI *)(const struct sockaddr *, socklen_t, char *, DWORD, char *, DWORD, int)) GetProcAddress(ipv6_dll, "getnameinfo"); if (!ipv6_freeaddrinfo || !ipv6_getaddrinfo || !ipv6_getnameinfo) { FreeLibrary(ipv6_dll); ipv6_dll = NULL; } else break; } if (!ipv6_freeaddrinfo || !ipv6_getaddrinfo || !ipv6_getnameinfo) { ipv6_freeaddrinfo = freeaddrinfo_stub; ipv6_getaddrinfo = getaddrinfo_stub; ipv6_getnameinfo = getnameinfo_stub; } atexit(socket_cleanup); initialized = 1; } #undef gethostname int mingw_gethostname(char *name, int namelen) { ensure_socket_initialization(); return gethostname(name, namelen); } #undef gethostbyname struct hostent *mingw_gethostbyname(const char *host) { ensure_socket_initialization(); return gethostbyname(host); } void mingw_freeaddrinfo(struct addrinfo *res) { ipv6_freeaddrinfo(res); } int mingw_getaddrinfo(const char *node, const char *service, const struct addrinfo *hints, struct addrinfo **res) { ensure_socket_initialization(); return ipv6_getaddrinfo(node, service, hints, res); } int mingw_getnameinfo(const struct sockaddr *sa, socklen_t salen, char *host, DWORD hostlen, char *serv, DWORD servlen, int flags) { ensure_socket_initialization(); return ipv6_getnameinfo(sa, salen, host, hostlen, serv, servlen, flags); } int mingw_socket(int domain, int type, int protocol) { int sockfd; SOCKET s; ensure_socket_initialization(); s = WSASocket(domain, type, protocol, NULL, 0, 0); if (s == INVALID_SOCKET) { /* * WSAGetLastError() values are regular BSD error codes * biased by WSABASEERR. * However, strerror() does not know about networking * specific errors, which are values beginning at 38 or so. * Therefore, we choose to leave the biased error code * in errno so that _if_ someone looks up the code somewhere, * then it is at least the number that are usually listed. */ errno = WSAGetLastError(); return -1; } /* convert into a file descriptor */ if ((sockfd = _open_osfhandle(s, O_RDWR|O_BINARY)) < 0) { closesocket(s); return error("unable to make a socket file descriptor: %s", strerror(errno)); } return sockfd; } #undef connect int mingw_connect(int sockfd, struct sockaddr *sa, size_t sz) { SOCKET s = (SOCKET)_get_osfhandle(sockfd); return connect(s, sa, sz); } #undef bind int mingw_bind(int sockfd, struct sockaddr *sa, size_t sz) { SOCKET s = (SOCKET)_get_osfhandle(sockfd); return bind(s, sa, sz); } #undef setsockopt int mingw_setsockopt(int sockfd, int lvl, int optname, void *optval, int optlen) { SOCKET s = (SOCKET)_get_osfhandle(sockfd); return setsockopt(s, lvl, optname, (const char*)optval, optlen); } #undef shutdown int mingw_shutdown(int sockfd, int how) { SOCKET s = (SOCKET)_get_osfhandle(sockfd); return shutdown(s, how); } #undef listen int mingw_listen(int sockfd, int backlog) { SOCKET s = (SOCKET)_get_osfhandle(sockfd); return listen(s, backlog); } #undef accept int mingw_accept(int sockfd1, struct sockaddr *sa, socklen_t *sz) { int sockfd2; SOCKET s1 = (SOCKET)_get_osfhandle(sockfd1); SOCKET s2 = accept(s1, sa, sz); /* convert into a file descriptor */ if ((sockfd2 = _open_osfhandle(s2, O_RDWR|O_BINARY)) < 0) { int err = errno; closesocket(s2); return error("unable to make a socket file descriptor: %s", strerror(err)); } return sockfd2; } #undef rename int mingw_rename(const char *pold, const char *pnew) { DWORD attrs, gle; int tries = 0; /* * Try native rename() first to get errno right. * It is based on MoveFile(), which cannot overwrite existing files. */ if (!rename(pold, pnew)) return 0; if (errno != EEXIST) return -1; repeat: if (MoveFileEx(pold, pnew, MOVEFILE_REPLACE_EXISTING)) return 0; /* TODO: translate more errors */ gle = GetLastError(); if (gle == ERROR_ACCESS_DENIED && (attrs = GetFileAttributes(pnew)) != INVALID_FILE_ATTRIBUTES) { if (attrs & FILE_ATTRIBUTE_DIRECTORY) { errno = EISDIR; return -1; } if ((attrs & FILE_ATTRIBUTE_READONLY) && SetFileAttributes(pnew, attrs & ~FILE_ATTRIBUTE_READONLY)) { if (MoveFileEx(pold, pnew, MOVEFILE_REPLACE_EXISTING)) return 0; gle = GetLastError(); /* revert file attributes on failure */ SetFileAttributes(pnew, attrs); } } if (tries < ARRAY_SIZE(delay) && gle == ERROR_ACCESS_DENIED) { /* * We assume that some other process had the source or * destination file open at the wrong moment and retry. * In order to give the other process a higher chance to * complete its operation, we give up our time slice now. * If we have to retry again, we do sleep a bit. */ Sleep(delay[tries]); tries++; goto repeat; } if (gle == ERROR_ACCESS_DENIED && ask_yes_no_if_possible("Rename from '%s' to '%s' failed. " "Should I try again?", pold, pnew)) goto repeat; errno = EACCES; return -1; } /* * Note that this doesn't return the actual pagesize, but * the allocation granularity. If future Windows specific git code * needs the real getpagesize function, we need to find another solution. */ int mingw_getpagesize(void) { SYSTEM_INFO si; GetSystemInfo(&si); return si.dwAllocationGranularity; } struct passwd *getpwuid(int uid) { static char user_name[100]; static struct passwd p; DWORD len = sizeof(user_name); if (!GetUserName(user_name, &len)) return NULL; p.pw_name = user_name; p.pw_gecos = "unknown"; p.pw_dir = NULL; return &p; } static HANDLE timer_event; static HANDLE timer_thread; static int timer_interval; static int one_shot; static sig_handler_t timer_fn = SIG_DFL, sigint_fn = SIG_DFL; /* The timer works like this: * The thread, ticktack(), is a trivial routine that most of the time * only waits to receive the signal to terminate. The main thread tells * the thread to terminate by setting the timer_event to the signalled * state. * But ticktack() interrupts the wait state after the timer's interval * length to call the signal handler. */ static unsigned __stdcall ticktack(void *dummy) { while (WaitForSingleObject(timer_event, timer_interval) == WAIT_TIMEOUT) { mingw_raise(SIGALRM); if (one_shot) break; } return 0; } static int start_timer_thread(void) { timer_event = CreateEvent(NULL, FALSE, FALSE, NULL); if (timer_event) { timer_thread = (HANDLE) _beginthreadex(NULL, 0, ticktack, NULL, 0, NULL); if (!timer_thread ) return errno = ENOMEM, error("cannot start timer thread"); } else return errno = ENOMEM, error("cannot allocate resources for timer"); return 0; } static void stop_timer_thread(void) { if (timer_event) SetEvent(timer_event); /* tell thread to terminate */ if (timer_thread) { int rc = WaitForSingleObject(timer_thread, 1000); if (rc == WAIT_TIMEOUT) error("timer thread did not terminate timely"); else if (rc != WAIT_OBJECT_0) error("waiting for timer thread failed: %lu", GetLastError()); CloseHandle(timer_thread); } if (timer_event) CloseHandle(timer_event); timer_event = NULL; timer_thread = NULL; } static inline int is_timeval_eq(const struct timeval *i1, const struct timeval *i2) { return i1->tv_sec == i2->tv_sec && i1->tv_usec == i2->tv_usec; } int setitimer(int type, struct itimerval *in, struct itimerval *out) { static const struct timeval zero; static int atexit_done; if (out != NULL) return errno = EINVAL, error("setitimer param 3 != NULL not implemented"); if (!is_timeval_eq(&in->it_interval, &zero) && !is_timeval_eq(&in->it_interval, &in->it_value)) return errno = EINVAL, error("setitimer: it_interval must be zero or eq it_value"); if (timer_thread) stop_timer_thread(); if (is_timeval_eq(&in->it_value, &zero) && is_timeval_eq(&in->it_interval, &zero)) return 0; timer_interval = in->it_value.tv_sec * 1000 + in->it_value.tv_usec / 1000; one_shot = is_timeval_eq(&in->it_interval, &zero); if (!atexit_done) { atexit(stop_timer_thread); atexit_done = 1; } return start_timer_thread(); } int sigaction(int sig, struct sigaction *in, struct sigaction *out) { if (sig != SIGALRM) return errno = EINVAL, error("sigaction only implemented for SIGALRM"); if (out != NULL) return errno = EINVAL, error("sigaction: param 3 != NULL not implemented"); timer_fn = in->sa_handler; return 0; } #undef signal sig_handler_t mingw_signal(int sig, sig_handler_t handler) { sig_handler_t old = timer_fn; switch (sig) { case SIGALRM: timer_fn = handler; break; case SIGINT: sigint_fn = handler; break; default: return signal(sig, handler); } return old; } #undef raise int mingw_raise(int sig) { switch (sig) { case SIGALRM: if (timer_fn == SIG_DFL) { if (isatty(STDERR_FILENO)) fputs("Alarm clock\n", stderr); exit(128 + SIGALRM); } else if (timer_fn != SIG_IGN) timer_fn(SIGALRM); return 0; case SIGINT: if (sigint_fn == SIG_DFL) exit(128 + SIGINT); else if (sigint_fn != SIG_IGN) sigint_fn(SIGINT); return 0; default: return raise(sig); } } static const char *make_backslash_path(const char *path) { static char buf[PATH_MAX + 1]; char *c; if (strlcpy(buf, path, PATH_MAX) >= PATH_MAX) die("Too long path: %.*s", 60, path); for (c = buf; *c; c++) { if (*c == '/') *c = '\\'; } return buf; } void mingw_open_html(const char *unixpath) { const char *htmlpath = make_backslash_path(unixpath); typedef HINSTANCE (WINAPI *T)(HWND, const char *, const char *, const char *, const char *, INT); T ShellExecute; HMODULE shell32; int r; shell32 = LoadLibrary("shell32.dll"); if (!shell32) die("cannot load shell32.dll"); ShellExecute = (T)GetProcAddress(shell32, "ShellExecuteA"); if (!ShellExecute) die("cannot run browser"); printf("Launching default browser to display HTML ...\n"); r = (int)ShellExecute(NULL, "open", htmlpath, NULL, "\\", SW_SHOWNORMAL); FreeLibrary(shell32); /* see the MSDN documentation referring to the result codes here */ if (r <= 32) { die("failed to launch browser for %.*s", MAX_PATH, unixpath); } } int link(const char *oldpath, const char *newpath) { typedef BOOL (WINAPI *T)(const char*, const char*, LPSECURITY_ATTRIBUTES); static T create_hard_link = NULL; if (!create_hard_link) { create_hard_link = (T) GetProcAddress( GetModuleHandle("kernel32.dll"), "CreateHardLinkA"); if (!create_hard_link) create_hard_link = (T)-1; } if (create_hard_link == (T)-1) { errno = ENOSYS; return -1; } if (!create_hard_link(newpath, oldpath, NULL)) { errno = err_win_to_posix(GetLastError()); return -1; } return 0; } pid_t waitpid(pid_t pid, int *status, int options) { HANDLE h = OpenProcess(SYNCHRONIZE | PROCESS_QUERY_INFORMATION, FALSE, pid); if (!h) { errno = ECHILD; return -1; } if (pid > 0 && options & WNOHANG) { if (WAIT_OBJECT_0 != WaitForSingleObject(h, 0)) { CloseHandle(h); return 0; } options &= ~WNOHANG; } if (options == 0) { struct pinfo_t **ppinfo; if (WaitForSingleObject(h, INFINITE) != WAIT_OBJECT_0) { CloseHandle(h); return 0; } if (status) GetExitCodeProcess(h, (LPDWORD)status); EnterCriticalSection(&pinfo_cs); ppinfo = &pinfo; while (*ppinfo) { struct pinfo_t *info = *ppinfo; if (info->pid == pid) { CloseHandle(info->proc); *ppinfo = info->next; free(info); break; } ppinfo = &info->next; } LeaveCriticalSection(&pinfo_cs); CloseHandle(h); return pid; } CloseHandle(h); errno = EINVAL; return -1; }