// The utility library for universal variables. Used both by the client library and by the daemon. #include "config.h" // IWYU pragma: keep #include // IWYU pragma: keep #include #include // We need the sys/file.h for the flock() declaration on Linux but not OS X. #include // IWYU pragma: keep // We need the ioctl.h header so we can check if SIOCGIFHWADDR is defined by it so we know if we're // on a Linux system. #include #include // IWYU pragma: keep #include // IWYU pragma: keep #if !defined(__APPLE__) && !defined(__CYGWIN__) #include #endif #include #include #include #include #ifdef __CYGWIN__ #include #endif #ifdef HAVE_SYS_SELECT_H #include // IWYU pragma: keep #endif #include #include // IWYU pragma: keep #include // IWYU pragma: keep #include #include #include #include #include #include #include #include "common.h" #include "env.h" #include "env_universal_common.h" #include "fallback.h" // IWYU pragma: keep #include "path.h" #include "utf8.h" #include "util.h" // IWYU pragma: keep #include "wutil.h" #if __APPLE__ #define FISH_NOTIFYD_AVAILABLE 1 #include #endif #ifdef __HAIKU__ #define _BSD_SOURCE #include #endif // Haiku // NAME_MAX is not defined on Solaris and suggests the use of pathconf() // There is no obvious sensible pathconf() for shared memory and _XPG_NAME_MAX // seems a reasonable choice. #if !defined(NAME_MAX) && defined(_XOPEN_NAME_MAX) #define NAME_MAX _XOPEN_NAME_MAX #endif /// The set command. #define SET_STR L"SET" /// The set_export command. #define SET_EXPORT_STR L"SET_EXPORT" /// Non-wide version of the set command. #define SET_MBS "SET" /// Non-wide version of the set_export command. #define SET_EXPORT_MBS "SET_EXPORT" /// Error message. #define PARSE_ERR L"Unable to parse universal variable message: '%ls'" /// Small note about not editing ~/.fishd manually. Inserted at the top of all .fishd files. #define SAVE_MSG \ "# This file is automatically generated by the fish.\n# Do NOT edit it directly, your " \ "changes will be overwritten.\n" static wcstring get_machine_identifier(); static bool get_hostname_identifier(wcstring *result); static wcstring vars_filename_in_directory(const wcstring &wdir) { if (wdir.empty()) return L""; wcstring result = wdir; result.append(L"/fishd."); result.append(get_machine_identifier()); return result; } static const wcstring default_vars_path() { wcstring path; path_get_config(path); return vars_filename_in_directory(path); } #if !defined(__APPLE__) && !defined(__CYGWIN__) /// Check, and create if necessary, a secure runtime path. Derived from tmux.c in tmux /// (http://tmux.sourceforge.net/). static int check_runtime_path(const char *path) { // Copyright (c) 2007 Nicholas Marriott // // Permission to use, copy, modify, and distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice appear in all copies. // // THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES // WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR // ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES // WHATSOEVER RESULTING FROM LOSS OF MIND, USE, DATA OR PROFITS, WHETHER // IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING // OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. struct stat statpath; uid_t uid = geteuid(); if (mkdir(path, S_IRWXU) != 0 && errno != EEXIST) return errno; if (lstat(path, &statpath) != 0) return errno; if (!S_ISDIR(statpath.st_mode) || statpath.st_uid != uid || (statpath.st_mode & (S_IRWXG | S_IRWXO)) != 0) return EACCES; return 0; } /// Return the path of an appropriate runtime data directory. static wcstring get_runtime_path() { wcstring result; const char *dir = getenv("XDG_RUNTIME_DIR"); // Check that the path is actually usable. Technically this is guaranteed by the fdo spec but in // practice it is not always the case: see #1828 and #2222. int mode = R_OK | W_OK | X_OK; if (dir != NULL && access(dir, mode) == 0 && check_runtime_path(dir) == 0) { result = str2wcstring(dir); } else { const char *uname = getenv("USER"); // $USER should already have been set (in setup_path()). // If it still isn't, there's something wrong. if (!uname) { return result; } // /tmp/fish.user std::string tmpdir = "/tmp/fish."; tmpdir.append(uname); if (check_runtime_path(tmpdir.c_str()) != 0) { debug(0, L"Runtime path not available."); debug(0, L"Try deleting the directory %s and restarting fish.", tmpdir.c_str()); } else { result = str2wcstring(tmpdir); } } return result; } /// Returns a "variables" file in the appropriate runtime directory. This is called infrequently and /// so does not need to be cached. static wcstring default_named_pipe_path() { // Note that vars_filename_in_directory returns empty string when passed the empty string. return vars_filename_in_directory(get_runtime_path()); } #endif /// Test if the message msg contains the command cmd. static bool match(const wchar_t *msg, const wchar_t *cmd) { size_t len = wcslen(cmd); if (wcsncasecmp(msg, cmd, len) != 0) return false; if (msg[len] && msg[len] != L' ' && msg[len] != L'\t') return false; return true; } /// The universal variable format has some funny escaping requirements; here we try to be safe. static bool is_universal_safe_to_encode_directly(wchar_t c) { if (c < 32 || c > 128) return false; return iswalnum(c) || wcschr(L"/_", c); } /// Escape specified string. static wcstring full_escape(const wchar_t *in) { wcstring out; for (; *in; in++) { wchar_t c = *in; if (is_universal_safe_to_encode_directly(c)) { out.push_back(c); } else if (c <= (wchar_t)ASCII_MAX) { // See #1225 for discussion of use of ASCII_MAX here. append_format(out, L"\\x%.2x", c); } else if (c < 65536) { append_format(out, L"\\u%.4x", c); } else { append_format(out, L"\\U%.8x", c); } } return out; } /// Converts input to UTF-8 and appends it to receiver, using storage as temp storage. static bool append_utf8(const wcstring &input, std::string *receiver, std::string *storage) { bool result = false; if (wchar_to_utf8_string(input, storage)) { receiver->append(*storage); result = true; } return result; } /// Creates a file entry like "SET fish_color_cwd:FF0". Appends the result to *result (as UTF8). /// Returns true on success. storage may be used for temporary storage, to avoid allocations. static bool append_file_entry(fish_message_type_t type, const wcstring &key_in, const wcstring &val_in, std::string *result, std::string *storage) { assert(storage != NULL); assert(result != NULL); // Record the length on entry, in case we need to back up. bool success = true; const size_t result_length_on_entry = result->size(); // Append header like "SET " result->append(type == SET ? SET_MBS : SET_EXPORT_MBS); result->push_back(' '); // Append variable name like "fish_color_cwd". if (!valid_var_name(key_in)) { debug(0, L"Illegal variable name: '%ls'", key_in.c_str()); success = false; } if (success && !append_utf8(key_in, result, storage)) { debug(0, L"Could not convert %ls to narrow character string", key_in.c_str()); success = false; } // Append ":". if (success) { result->push_back(':'); } // Append value. if (success && !append_utf8(full_escape(val_in.c_str()), result, storage)) { debug(0, L"Could not convert %ls to narrow character string", val_in.c_str()); success = false; } // Append newline. if (success) { result->push_back('\n'); } // Don't modify result on failure. It's sufficient to simply resize it since all we ever did was // append to it. if (!success) { result->resize(result_length_on_entry); } return success; } env_universal_t::env_universal_t(const wcstring &path) : explicit_vars_path(path), tried_renaming(false), last_read_file(kInvalidFileID) { DIE_ON_FAILURE(pthread_mutex_init(&lock, NULL)); } env_universal_t::~env_universal_t() { pthread_mutex_destroy(&lock); } env_var_t env_universal_t::get(const wcstring &name) const { env_var_t result = env_var_t::missing_var(); var_table_t::const_iterator where = vars.find(name); if (where != vars.end()) { result = env_var_t(where->second.val); } return result; } bool env_universal_t::get_export(const wcstring &name) const { bool result = false; var_table_t::const_iterator where = vars.find(name); if (where != vars.end()) { result = where->second.exportv; } return result; } void env_universal_t::set_internal(const wcstring &key, const wcstring &val, bool exportv, bool overwrite) { ASSERT_IS_LOCKED(lock); if (!overwrite && this->modified.find(key) != this->modified.end()) { // This value has been modified and we're not overwriting it. Skip it. return; } var_entry_t *entry = &vars[key]; if (entry->exportv != exportv || entry->val != val) { entry->val = val; entry->exportv = exportv; // If we are overwriting, then this is now modified. if (overwrite) { this->modified.insert(key); } } } void env_universal_t::set(const wcstring &key, const wcstring &val, bool exportv) { scoped_lock locker(lock); this->set_internal(key, val, exportv, true /* overwrite */); } bool env_universal_t::remove_internal(const wcstring &key) { ASSERT_IS_LOCKED(lock); size_t erased = this->vars.erase(key); if (erased > 0) { this->modified.insert(key); } return erased > 0; } bool env_universal_t::remove(const wcstring &key) { scoped_lock locker(lock); return this->remove_internal(key); } wcstring_list_t env_universal_t::get_names(bool show_exported, bool show_unexported) const { wcstring_list_t result; scoped_lock locker(lock); var_table_t::const_iterator iter; for (iter = vars.begin(); iter != vars.end(); ++iter) { const wcstring &key = iter->first; const var_entry_t &e = iter->second; if ((e.exportv && show_exported) || (!e.exportv && show_unexported)) { result.push_back(key); } } return result; } // Given a variable table, generate callbacks representing the difference between our vars and the // new vars. void env_universal_t::generate_callbacks(const var_table_t &new_vars, callback_data_list_t &callbacks) const { // Construct callbacks for erased values. for (var_table_t::const_iterator iter = this->vars.begin(); iter != this->vars.end(); ++iter) { const wcstring &key = iter->first; // Skip modified values. if (this->modified.find(key) != this->modified.end()) { continue; } // If the value is not present in new_vars, it has been erased. if (new_vars.find(key) == new_vars.end()) { callbacks.push_back(callback_data_t(ERASE, key, L"")); } } // Construct callbacks for newly inserted or changed values. for (var_table_t::const_iterator iter = new_vars.begin(); iter != new_vars.end(); ++iter) { const wcstring &key = iter->first; // Skip modified values. if (this->modified.find(key) != this->modified.end()) { continue; } // See if the value has changed. const var_entry_t &new_entry = iter->second; var_table_t::const_iterator existing = this->vars.find(key); if (existing == this->vars.end() || existing->second.exportv != new_entry.exportv || existing->second.val != new_entry.val) { // Value has changed. callbacks.push_back( callback_data_t(new_entry.exportv ? SET_EXPORT : SET, key, new_entry.val)); } } } void env_universal_t::acquire_variables(var_table_t *vars_to_acquire) { // Copy modified values from existing vars to vars_to_acquire. for (std::set::iterator iter = this->modified.begin(); iter != this->modified.end(); ++iter) { const wcstring &key = *iter; var_table_t::iterator src_iter = this->vars.find(key); if (src_iter == this->vars.end()) { /* The value has been deleted. */ vars_to_acquire->erase(key); } else { // The value has been modified. Copy it over. Note we can destructively modify the // source entry in vars since we are about to get rid of this->vars entirely. var_entry_t &src = src_iter->second; var_entry_t &dst = (*vars_to_acquire)[key]; dst.val = std::move(src.val); dst.exportv = src.exportv; } } // We have constructed all the callbacks and updated vars_to_acquire. Acquire it! this->vars = std::move(*vars_to_acquire); } void env_universal_t::load_from_fd(int fd, callback_data_list_t &callbacks) { ASSERT_IS_LOCKED(lock); assert(fd >= 0); // Get the dev / inode. const file_id_t current_file = file_id_for_fd(fd); if (current_file == last_read_file) { debug(5, L"universal log sync elided based on fstat()"); } else { // Read a variables table from the file. var_table_t new_vars = this->read_message_internal(fd); // Announce changes. this->generate_callbacks(new_vars, callbacks); // Acquire the new variables. this->acquire_variables(&new_vars); last_read_file = current_file; } } bool env_universal_t::load_from_path(const wcstring &path, callback_data_list_t &callbacks) { ASSERT_IS_LOCKED(lock); // Check to see if the file is unchanged. We do this again in load_from_fd, but this avoids // opening the file unnecessarily. if (last_read_file != kInvalidFileID && file_id_for_path(path) == last_read_file) { debug(5, L"universal log sync elided based on fast stat()"); return true; } bool result = false; int fd = wopen_cloexec(path, O_RDONLY); if (fd >= 0) { debug(5, L"universal log reading from file"); this->load_from_fd(fd, callbacks); close(fd); result = true; } return result; } /// Writes our state to the fd. path is provided only for error reporting. bool env_universal_t::write_to_fd(int fd, const wcstring &path) { ASSERT_IS_LOCKED(lock); assert(fd >= 0); bool success = true; // Stuff we output to fd. std::string contents; // Temporary storage. std::string storage; // Write the save message. If this fails, we don't bother complaining. write_loop(fd, SAVE_MSG, strlen(SAVE_MSG)); var_table_t::const_iterator iter = vars.begin(); while (iter != vars.end()) { // Append the entry. Note that append_file_entry may fail, but that only affects one // variable; soldier on. const wcstring &key = iter->first; const var_entry_t &entry = iter->second; append_file_entry(entry.exportv ? SET_EXPORT : SET, key, entry.val, &contents, &storage); // Go to next. ++iter; // Flush if this is the last iteration or we exceed a page. if (iter == vars.end() || contents.size() >= 4096) { if (write_loop(fd, contents.data(), contents.size()) < 0) { const char *error = strerror(errno); debug(0, _(L"Unable to write to universal variables file '%ls': %s"), path.c_str(), error); success = false; break; } contents.clear(); } } // Since we just wrote out this file, it matches our internal state; pretend we read from it. this->last_read_file = file_id_for_fd(fd); // We don't close the file. return success; } bool env_universal_t::move_new_vars_file_into_place(const wcstring &src, const wcstring &dst) { int ret = wrename(src, dst); if (ret != 0) { const char *error = strerror(errno); debug(0, _(L"Unable to rename file from '%ls' to '%ls': %s"), src.c_str(), dst.c_str(), error); } return ret == 0; } bool env_universal_t::load(callback_data_list_t &callbacks) { const wcstring vars_path = explicit_vars_path.empty() ? default_vars_path() : explicit_vars_path; scoped_lock locker(lock); bool success = load_from_path(vars_path, callbacks); if (!success && !tried_renaming && errno == ENOENT) { // We failed to load, because the file was not found. Older fish used the hostname only. Try // moving the filename based on the hostname into place; if that succeeds try again. // Silently "upgraded." tried_renaming = true; wcstring hostname_id; if (get_hostname_identifier(&hostname_id)) { const wcstring hostname_path = wdirname(vars_path) + L'/' + hostname_id; if (0 == wrename(hostname_path, vars_path)) { // We renamed - try again. success = this->load(callbacks); } } } return success; } bool env_universal_t::open_temporary_file(const wcstring &directory, wcstring *out_path, int *out_fd) { // Create and open a temporary file for writing within the given directory. Try to create a // temporary file, up to 10 times. We don't use mkstemps because we want to open it CLO_EXEC. // This should almost always succeed on the first try. assert(!string_suffixes_string(L"/", directory)); //!OCLINT(multiple unary operator) bool success = false; int saved_errno; const wcstring tmp_name_template = directory + L"/fishd.tmp.XXXXXX"; for (size_t attempt = 0; attempt < 10 && !success; attempt++) { char *narrow_str = wcs2str(tmp_name_template.c_str()); int result_fd = fish_mkstemp_cloexec(narrow_str); saved_errno = errno; success = result_fd != -1; *out_fd = result_fd; *out_path = str2wcstring(narrow_str); free(narrow_str); } if (!success) { const char *error = strerror(saved_errno); debug(0, _(L"Unable to open temporary file '%ls': %s"), out_path->c_str(), error); } return success; } /// Check how long the operation took and print a message if it took too long. /// Returns false if it took too long else true. static bool check_duration(double start_time) { double duration = timef() - start_time; if (duration > 0.25) { debug(1, _(L"Locking the universal var file took too long (%.3f seconds)."), duration); return false; } return true; } /// Try locking the file. Return true if we succeeded else false. This is safe in terms of the /// fallback function implemented in terms of fcntl: only ever run on the main thread, and protected /// by the universal variable lock. static bool lock_uvar_file(int fd) { double start_time = timef(); while (flock(fd, LOCK_EX) == -1) { if (errno != EINTR) return false; // do nothing per issue #2149 } return check_duration(start_time); } bool env_universal_t::open_and_acquire_lock(const wcstring &path, int *out_fd) { // Attempt to open the file for reading at the given path, atomically acquiring a lock. On BSD, // we can use O_EXLOCK. On Linux, we open the file, take a lock, and then compare fstat() to // stat(); if they match, it means that the file was not replaced before we acquired the lock. // // We pass O_RDONLY with O_CREAT; this creates a potentially empty file. We do this so that we // have something to lock on. static std::atomic do_locking(true); bool needs_lock = true; int flags = O_RDWR | O_CREAT; #ifdef O_EXLOCK if (do_locking) { flags |= O_EXLOCK; needs_lock = false; } #endif int fd = -1; while (fd == -1) { double start_time = timef(); fd = wopen_cloexec(path, flags, 0644); if (fd == -1) { if (errno == EINTR) continue; // signaled; try again #ifdef O_EXLOCK if (do_locking && (errno == ENOTSUP || errno == EOPNOTSUPP)) { // Filesystem probably does not support locking. Clear the flag and try again. Note // that we try taking the lock via flock anyways. Note that on Linux the two errno // symbols have the same value but on BSD they're different. flags &= ~O_EXLOCK; needs_lock = true; continue; } #endif const char *error = strerror(errno); debug(0, _(L"Unable to open universal variable file '%ls': %s"), path.c_str(), error); break; } assert(fd >= 0); // if we get here, we must have a valid fd if (!needs_lock && do_locking) { do_locking = check_duration(start_time); } // Try taking the lock, if necessary. If we failed, we may be on lockless NFS, etc.; in that // case we pretend we succeeded. See the comment in save_to_path for the rationale. if (needs_lock && do_locking) { do_locking = lock_uvar_file(fd); } // Hopefully we got the lock. However, it's possible the file changed out from under us // while we were waiting for the lock. Make sure that didn't happen. if (file_id_for_fd(fd) != file_id_for_path(path)) { // Oops, it changed! Try again. close(fd); fd = -1; } } *out_fd = fd; return fd >= 0; } // Returns true if modified variables were written, false if not. (There may still be variable // changes due to other processes on a false return). bool env_universal_t::sync(callback_data_list_t &callbacks) { debug(5, L"universal log sync"); scoped_lock locker(lock); // Our saving strategy: // // 1. Open the file, producing an fd. // 2. Lock the file (may be combined with step 1 on systems with O_EXLOCK) // 3. After taking the lock, check if the file at the given path is different from what we // opened. If so, start over. // 4. Read from the file. This can be elided if its dev/inode is unchanged since the last read // 5. Open an adjacent temporary file // 6. Write our changes to an adjacent file // 7. Move the adjacent file into place via rename. This is assumed to be atomic. // 8. Release the lock and close the file // // Consider what happens if Process 1 and 2 both do this simultaneously. Can there be data loss? // Process 1 opens the file and then attempts to take the lock. Now, either process 1 will see // the original file, or process 2's new file. If it sees the new file, we're OK: it's going to // read from the new file, and so there's no data loss. If it sees the old file, then process 2 // must have locked it (if process 1 locks it, switch their roles). The lock will block until // process 2 reaches step 7; at that point process 1 will reach step 2, notice that the file has // changed, and then start over. // // It's possible that the underlying filesystem does not support locks (lockless NFS). In this // case, we risk data loss if two shells try to write their universal variables simultaneously. // In practice this is unlikely, since uvars are usually written interactively. // // Prior versions of fish used a hard link scheme to support file locking on lockless NFS. The // risk here is that if the process crashes or is killed while holding the lock, future // instances of fish will not be able to obtain it. This seems to be a greater risk than that of // data loss on lockless NFS. Users who put their home directory on lockless NFS are playing // with fire anyways. const wcstring &vars_path = explicit_vars_path.empty() ? default_vars_path() : explicit_vars_path; if (vars_path.empty()) { debug(2, L"No universal variable path available"); return false; } // If we have no changes, just load. if (modified.empty()) { this->load_from_path(vars_path, callbacks); debug(5, L"universal log no modifications"); return false; } const wcstring directory = wdirname(vars_path); bool success = true; int vars_fd = -1; int private_fd = -1; wcstring private_file_path; debug(5, L"universal log performing full sync"); // Open the file. if (success) { success = this->open_and_acquire_lock(vars_path, &vars_fd); if (!success) debug(5, L"universal log open_and_acquire_lock() failed"); } // Read from it. if (success) { assert(vars_fd >= 0); this->load_from_fd(vars_fd, callbacks); } // Open adjacent temporary file. if (success) { success = this->open_temporary_file(directory, &private_file_path, &private_fd); if (!success) debug(5, L"universal log open_temporary_file() failed"); } // Write to it. if (success) { assert(private_fd >= 0); success = this->write_to_fd(private_fd, private_file_path); if (!success) debug(5, L"universal log write_to_fd() failed"); } if (success) { // Ensure we maintain ownership and permissions (#2176). struct stat sbuf; if (wstat(vars_path, &sbuf) >= 0) { if (fchown(private_fd, sbuf.st_uid, sbuf.st_gid) == -1) debug(5, L"universal log fchown() failed"); if (fchmod(private_fd, sbuf.st_mode) == -1) debug(5, L"universal log fchmod() failed"); } // Linux by default stores the mtime with low precision, low enough that updates that occur in quick // succession may result in the same mtime (even the nanoseconds field). So manually set the mtime // of the new file to a high-precision clock. Note that this is only necessary because Linux // aggressively reuses inodes, causing the ABA problem; on other platforms we tend to notice the // file has changed due to a different inode (or file size!) // // It's probably worth finding a simpler solution to this. The tests ran into this, but it's // unlikely to affect users. #if HAVE_CLOCK_GETTIME && HAVE_FUTIMENS struct timespec times[2] = {}; times[0].tv_nsec = UTIME_OMIT; // don't change ctime if (0 == clock_gettime(CLOCK_REALTIME, ×[1])) { futimens(private_fd, times); } #endif // Apply new file. success = this->move_new_vars_file_into_place(private_file_path, vars_path); if (!success) debug(5, L"universal log move_new_vars_file_into_place() failed"); } if (success) { // Since we moved the new file into place, clear the path so we don't try to unlink it. private_file_path.clear(); } // Clean up. if (vars_fd >= 0) { close(vars_fd); } if (private_fd >= 0) { close(private_fd); } if (!private_file_path.empty()) { wunlink(private_file_path); } if (success) { // All of our modified variables have now been written out. modified.clear(); } return success; } var_table_t env_universal_t::read_message_internal(int fd) { var_table_t result; // Temp value used to avoid repeated allocations. wcstring storage; // The line we construct (and then parse). std::string line; wcstring wide_line; for (;;) { // Read into a buffer. Note this is NOT null-terminated! char buffer[1024]; ssize_t amt = read_loop(fd, buffer, sizeof buffer); if (amt <= 0) { break; } const size_t bufflen = (size_t)amt; // Walk over it by lines. The contents of an unterminated line will be left in 'line' for // the next iteration. ssize_t line_start = 0; while (line_start < amt) { // Run until we hit a newline. size_t cursor = line_start; while (cursor < bufflen && buffer[cursor] != '\n') { cursor++; } // Copy over what we read. line.append(buffer + line_start, cursor - line_start); // Process it if it's a newline (which is true if we are before the end of the buffer). if (cursor < bufflen && !line.empty()) { if (utf8_to_wchar(line.data(), line.size(), &wide_line, 0)) { env_universal_t::parse_message_internal(wide_line, &result, &storage); } line.clear(); } // Skip over the newline (or skip past the end). line_start = cursor + 1; } } // We make no effort to handle an unterminated last line. return result; } /// Parse message msg/ void env_universal_t::parse_message_internal(const wcstring &msgstr, var_table_t *vars, wcstring *storage) { const wchar_t *msg = msgstr.c_str(); // debug(3, L"parse_message( %ls );", msg); if (msg[0] == L'#') return; bool is_set_export = match(msg, SET_EXPORT_STR); bool is_set = !is_set_export && match(msg, SET_STR); if (is_set || is_set_export) { const wchar_t *name, *tmp; const bool exportv = is_set_export; name = msg + (exportv ? wcslen(SET_EXPORT_STR) : wcslen(SET_STR)); while (name[0] == L'\t' || name[0] == L' ') name++; tmp = wcschr(name, L':'); if (tmp) { // Use 'storage' to hold our key to avoid allocations. storage->assign(name, tmp - name); const wcstring &key = *storage; wcstring val; if (unescape_string(tmp + 1, &val, 0)) { var_entry_t &entry = (*vars)[key]; entry.exportv = exportv; entry.val = std::move(val); // acquire the value } } else { debug(1, PARSE_ERR, msg); } } else { debug(1, PARSE_ERR, msg); } } /// Maximum length of hostname. Longer hostnames are truncated. #define HOSTNAME_LEN 32 /// Length of a MAC address. #define MAC_ADDRESS_MAX_LEN 6 // Thanks to Jan Brittenson, http://lists.apple.com/archives/xcode-users/2009/May/msg00062.html #ifdef SIOCGIFHWADDR // Linux #include #include static bool get_mac_address(unsigned char macaddr[MAC_ADDRESS_MAX_LEN], const char *interface = "eth0") { bool result = false; const int dummy = socket(AF_INET, SOCK_STREAM, 0); if (dummy >= 0) { struct ifreq r; strncpy((char *)r.ifr_name, interface, sizeof r.ifr_name - 1); r.ifr_name[sizeof r.ifr_name - 1] = 0; if (ioctl(dummy, SIOCGIFHWADDR, &r) >= 0) { memcpy(macaddr, r.ifr_hwaddr.sa_data, MAC_ADDRESS_MAX_LEN); result = true; } close(dummy); } return result; } #elif defined(HAVE_GETIFADDRS) // OS X and BSD #include #include #include static bool get_mac_address(unsigned char macaddr[MAC_ADDRESS_MAX_LEN], const char *interface = "en0") { // BSD, Mac OS X struct ifaddrs *ifap; bool ok = false; if (getifaddrs(&ifap) != 0) { return ok; } for (const ifaddrs *p = ifap; p; p = p->ifa_next) { bool is_af_link = p->ifa_addr && p->ifa_addr->sa_family == AF_LINK; if (is_af_link && p->ifa_name && p->ifa_name[0] && !strcmp((const char *)p->ifa_name, interface)) { const sockaddr_dl &sdl = *reinterpret_cast(p->ifa_addr); size_t alen = sdl.sdl_alen; if (alen > MAC_ADDRESS_MAX_LEN) alen = MAC_ADDRESS_MAX_LEN; memcpy(macaddr, sdl.sdl_data + sdl.sdl_nlen, alen); ok = true; break; } } freeifaddrs(ifap); return ok; } #else // Unsupported static bool get_mac_address(unsigned char macaddr[MAC_ADDRESS_MAX_LEN]) { return false; } #endif /// Function to get an identifier based on the hostname. static bool get_hostname_identifier(wcstring *result) { bool success = false; char hostname[HOSTNAME_LEN + 1] = {}; if (gethostname(hostname, HOSTNAME_LEN) == 0) { result->assign(str2wcstring(hostname)); success = true; } return success; } /// Get a sort of unique machine identifier. Prefer the MAC address; if that fails, fall back to the /// hostname; if that fails, pick something. wcstring get_machine_identifier() { wcstring result; unsigned char mac_addr[MAC_ADDRESS_MAX_LEN] = {}; if (get_mac_address(mac_addr)) { result.reserve(2 * MAC_ADDRESS_MAX_LEN); for (size_t i = 0; i < MAC_ADDRESS_MAX_LEN; i++) { append_format(result, L"%02x", mac_addr[i]); } } else if (!get_hostname_identifier(&result)) { result.assign(L"nohost"); // fallback to a dummy value } return result; } class universal_notifier_shmem_poller_t : public universal_notifier_t { #ifdef __CYGWIN__ // This is what our shared memory looks like. Everything here is stored in network byte order // (big-endian). struct universal_notifier_shmem_t { uint32_t magic; uint32_t version; uint32_t universal_variable_seed; }; #define SHMEM_MAGIC_NUMBER 0xF154 #define SHMEM_VERSION_CURRENT 1000 private: long long last_change_time; uint32_t last_seed; volatile universal_notifier_shmem_t *region; void open_shmem() { assert(region == NULL); // Use a path based on our uid to avoid collisions. char path[NAME_MAX]; snprintf(path, sizeof path, "/%ls_shmem_%d", program_name ? program_name : L"fish", getuid()); bool errored = false; int fd = shm_open(path, O_RDWR | O_CREAT, 0600); if (fd < 0) { const char *error = strerror(errno); debug(0, _(L"Unable to open shared memory with path '%s': %s"), path, error); errored = true; } // Get the size. off_t size = 0; if (!errored) { struct stat buf = {}; if (fstat(fd, &buf) < 0) { const char *error = strerror(errno); debug(0, _(L"Unable to fstat shared memory object with path '%s': %s"), path, error); errored = true; } size = buf.st_size; } // Set the size, if it's too small. bool set_size = !errored && size < (off_t)sizeof(universal_notifier_shmem_t); if (set_size && ftruncate(fd, sizeof(universal_notifier_shmem_t)) < 0) { const char *error = strerror(errno); debug(0, _(L"Unable to truncate shared memory object with path '%s': %s"), path, error); errored = true; } // Memory map the region. if (!errored) { void *addr = mmap(NULL, sizeof(universal_notifier_shmem_t), PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0); if (addr == MAP_FAILED) { const char *error = strerror(errno); debug(0, _(L"Unable to memory map shared memory object with path '%s': %s"), path, error); this->region = NULL; } else { this->region = static_cast(addr); } } // Close the fd, even if the mapping succeeded. if (fd >= 0) { close(fd); } // Read the current seed. this->poll(); } public: // Our notification involves changing the value in our shared memory. In practice, all clients // will be in separate processes, so it suffices to set the value to a pid. For testing // purposes, however, it's useful to keep them in the same process, so we increment the value. // This isn't "safe" in the sense that multiple simultaneous increments may result in one being // lost, but it should always result in the value being changed, which is sufficient. void post_notification() { if (region != NULL) { /* Read off the seed */ uint32_t seed = ntohl(region->universal_variable_seed); //!OCLINT(constant cond op) // Increment it. Don't let it wrap to zero. do { seed++; } while (seed == 0); last_seed = seed; // Write out our data. region->magic = htonl(SHMEM_MAGIC_NUMBER); //!OCLINT(constant cond op) region->version = htonl(SHMEM_VERSION_CURRENT); //!OCLINT(constant cond op) region->universal_variable_seed = htonl(seed); //!OCLINT(constant cond op) } } universal_notifier_shmem_poller_t() : last_change_time(0), last_seed(0), region(NULL) { open_shmem(); } ~universal_notifier_shmem_poller_t() { if (region != NULL) { // Behold: C++ in all its glory! void *address = const_cast(static_cast(region)); if (munmap(address, sizeof(universal_notifier_shmem_t)) < 0) { wperror(L"munmap"); } } } bool poll() { bool result = false; if (region != NULL) { uint32_t seed = ntohl(region->universal_variable_seed); //!OCLINT(constant cond op) if (seed != last_seed) { result = true; last_seed = seed; last_change_time = get_time(); } } return result; } unsigned long usec_delay_between_polls() const { // If it's been less than five seconds since the last change, we poll quickly Otherwise we // poll more slowly. Note that a poll is a very cheap shmem read. The bad part about making // this high is the process scheduling/wakeups it produces. long long usec_per_sec = 1000000; if (get_time() - last_change_time < 5LL * usec_per_sec) { return usec_per_sec / 10; // 10 times a second } return usec_per_sec / 3; // 3 times a second } #else // this class isn't valid on this system public: universal_notifier_shmem_poller_t() { DIE("universal_notifier_shmem_poller_t cannot be used on this system"); } #endif }; /// A notifyd-based notifier. Very straightforward. class universal_notifier_notifyd_t : public universal_notifier_t { #if FISH_NOTIFYD_AVAILABLE int notify_fd; int token; std::string name; void setup_notifyd() { // Per notify(3), the user.uid.%d style is only accessible to processes with that uid. char local_name[256]; snprintf(local_name, sizeof local_name, "user.uid.%d.%ls.uvars", getuid(), program_name ? program_name : L"fish"); name.assign(local_name); uint32_t status = notify_register_file_descriptor(name.c_str(), &this->notify_fd, 0, &this->token); if (status != NOTIFY_STATUS_OK) { debug(1, "notify_register_file_descriptor() failed with status %u.", status); debug(1, "Universal variable notifications may not be received."); } if (this->notify_fd >= 0) { // Mark us for non-blocking reads, and CLO_EXEC. int flags = fcntl(this->notify_fd, F_GETFL, 0); if (flags >= 0 && !(flags & O_NONBLOCK)) { fcntl(this->notify_fd, F_SETFL, flags | O_NONBLOCK); } set_cloexec(this->notify_fd); // Serious hack: notify_fd is likely the read end of a pipe. The other end is owned by // libnotify, which does not mark it as CLO_EXEC (it should!). The next fd is probably // notify_fd + 1. Do it ourselves. If the implementation changes and some other FD gets // marked as CLO_EXEC, that's probably a good thing. set_cloexec(this->notify_fd + 1); } } public: universal_notifier_notifyd_t() : notify_fd(-1), token(-1 /* NOTIFY_TOKEN_INVALID */) { setup_notifyd(); } ~universal_notifier_notifyd_t() { if (token != -1 /* NOTIFY_TOKEN_INVALID */) { notify_cancel(token); } } int notification_fd() { return notify_fd; } bool notification_fd_became_readable(int fd) { // notifyd notifications come in as 32 bit values. We don't care about the value. We set // ourselves as non-blocking, so just read until we can't read any more. assert(fd == notify_fd); bool read_something = false; unsigned char buff[64]; ssize_t amt_read; do { amt_read = read(notify_fd, buff, sizeof buff); read_something = (read_something || amt_read > 0); } while (amt_read == sizeof buff); return read_something; } void post_notification() { uint32_t status = notify_post(name.c_str()); if (status != NOTIFY_STATUS_OK) { debug(1, "notify_post() failed with status %u. Uvar notifications may not be sent.", status); } } #else // this class isn't valid on this system public: universal_notifier_notifyd_t() { DIE("universal_notifier_notifyd_t cannot be used on this system"); } #endif }; #if !defined(__APPLE__) && !defined(__CYGWIN__) #define NAMED_PIPE_FLASH_DURATION_USEC (1e5) #define SUSTAINED_READABILITY_CLEANUP_DURATION_USEC (5 * 1e6) #endif // Named-pipe based notifier. All clients open the same named pipe for reading and writing. The // pipe's readability status is a trigger to enter polling mode. // // To post a notification, write some data to the pipe, wait a little while, and then read it back. // // To receive a notification, watch for the pipe to become readable. When it does, enter a polling // mode until the pipe is no longer readable. To guard against the possibility of a shell exiting // when there is data remaining in the pipe, if the pipe is kept readable too long, clients will // attempt to read data out of it (to render it no longer readable). class universal_notifier_named_pipe_t : public universal_notifier_t { #if !defined(__APPLE__) && !defined(__CYGWIN__) int pipe_fd; long long readback_time_usec; size_t readback_amount; bool polling_due_to_readable_fd; long long drain_if_still_readable_time_usec; void make_pipe(const wchar_t *test_path); void drain_excessive_data() { // The pipe seems to have data on it, that won't go away. Read a big chunk out of it. We // don't read until it's exhausted, because if someone were to pipe say /dev/null, that // would cause us to hang! size_t read_amt = 64 * 1024; void *buff = malloc(read_amt); read_ignore(this->pipe_fd, buff, read_amt); free(buff); } public: universal_notifier_named_pipe_t(const wchar_t *test_path) : pipe_fd(-1), readback_time_usec(0), readback_amount(0), polling_due_to_readable_fd(false), drain_if_still_readable_time_usec(0) { make_pipe(test_path); } ~universal_notifier_named_pipe_t() { if (pipe_fd >= 0) { close(pipe_fd); } } int notification_fd() { if (polling_due_to_readable_fd) { // We are in polling mode because we think our fd is readable. This means that, if we // return it to be select()'d on, we'll be called back immediately. So don't return it. return -1; } // We are not in polling mode. Return the fd so it can be watched. return pipe_fd; } bool notification_fd_became_readable(int fd) { // Our fd is readable. We deliberately do not read anything out of it: if we did, other // sessions may miss the notification. Instead, we go into "polling mode:" we do not // select() on our fd for a while, and sync periodically until the fd is no longer readable. // However, if we are the one who posted the notification, we don't sync (until we clean // up!) UNUSED(fd); bool should_sync = false; if (readback_time_usec == 0) { polling_due_to_readable_fd = true; drain_if_still_readable_time_usec = get_time() + SUSTAINED_READABILITY_CLEANUP_DURATION_USEC; should_sync = true; } return should_sync; } void post_notification() { if (pipe_fd >= 0) { // We need to write some data (any data) to the pipe, then wait for a while, then read // it back. Nobody is expected to read it except us. int pid_nbo = htonl(getpid()); //!OCLINT(constant cond op) ssize_t amt_written = write(this->pipe_fd, &pid_nbo, sizeof pid_nbo); if (amt_written < 0 && (errno == EWOULDBLOCK || errno == EAGAIN)) { // Very unsual: the pipe is full! drain_excessive_data(); } // Now schedule a read for some time in the future. this->readback_time_usec = get_time() + NAMED_PIPE_FLASH_DURATION_USEC; this->readback_amount += sizeof pid_nbo; } } unsigned long usec_delay_between_polls() const { unsigned long readback_delay = ULONG_MAX; if (this->readback_time_usec > 0) { // How long until the readback? long long now = get_time(); if (now >= this->readback_time_usec) { // Oops, it already passed! Return something tiny. readback_delay = 1000; } else { readback_delay = (unsigned long)(this->readback_time_usec - now); } } unsigned long polling_delay = ULONG_MAX; if (polling_due_to_readable_fd) { // We're in polling mode. Don't return a value less than our polling interval. polling_delay = NAMED_PIPE_FLASH_DURATION_USEC; } // Now return the smaller of the two values. If we get ULONG_MAX, it means there's no more // need to poll; in that case return 0. unsigned long result = mini(readback_delay, polling_delay); if (result == ULONG_MAX) { result = 0; } return result; } bool poll() { // Check if we are past the readback time. if (this->readback_time_usec > 0 && get_time() >= this->readback_time_usec) { // Read back what we wrote. We do nothing with the value. while (this->readback_amount > 0) { char buff[64]; size_t amt_to_read = mini(this->readback_amount, sizeof buff); read_ignore(this->pipe_fd, buff, amt_to_read); this->readback_amount -= amt_to_read; } assert(this->readback_amount == 0); this->readback_time_usec = 0; } // Check to see if we are doing readability polling. if (!polling_due_to_readable_fd || pipe_fd < 0) { return false; } // We are polling, so we are definitely going to sync. // See if this is still readable. fd_set fds; FD_ZERO(&fds); FD_SET(this->pipe_fd, &fds); struct timeval timeout = {}; select(this->pipe_fd + 1, &fds, NULL, NULL, &timeout); if (!FD_ISSET(this->pipe_fd, &fds)) { // No longer readable, no longer polling. polling_due_to_readable_fd = false; drain_if_still_readable_time_usec = 0; } else { // Still readable. If it's been readable for a long time, there is probably // lingering data on the pipe. if (get_time() >= drain_if_still_readable_time_usec) { drain_excessive_data(); } } return true; } #else // this class isn't valid on this system public: universal_notifier_named_pipe_t(const wchar_t *test_path) { static_cast(test_path); DIE("universal_notifier_named_pipe_t cannot be used on this system"); } #endif }; universal_notifier_t::notifier_strategy_t universal_notifier_t::resolve_default_strategy() { #if FISH_NOTIFYD_AVAILABLE return strategy_notifyd; #elif defined(__CYGWIN__) return strategy_shmem_polling; #else return strategy_named_pipe; #endif } universal_notifier_t &universal_notifier_t::default_notifier() { static std::unique_ptr result = new_notifier_for_strategy(universal_notifier_t::resolve_default_strategy()); return *result; } std::unique_ptr universal_notifier_t::new_notifier_for_strategy( universal_notifier_t::notifier_strategy_t strat, const wchar_t *test_path) { switch (strat) { case strategy_notifyd: { return make_unique(); } case strategy_shmem_polling: { return make_unique(); } case strategy_named_pipe: { return make_unique(test_path); } } DIE("should never reach this statement"); return NULL; } // Default implementations. universal_notifier_t::universal_notifier_t() {} universal_notifier_t::~universal_notifier_t() {} int universal_notifier_t::notification_fd() { return -1; } void universal_notifier_t::post_notification() {} bool universal_notifier_t::poll() { return false; } unsigned long universal_notifier_t::usec_delay_between_polls() const { return 0; } bool universal_notifier_t::notification_fd_became_readable(int fd) { UNUSED(fd); return false; } #if !defined(__APPLE__) && !defined(__CYGWIN__) void universal_notifier_named_pipe_t::make_pipe(const wchar_t *test_path) { wcstring vars_path = test_path ? wcstring(test_path) : default_named_pipe_path(); vars_path.append(L".notifier"); const std::string narrow_path = wcs2string(vars_path); int mkfifo_status = mkfifo(narrow_path.c_str(), 0600); if (mkfifo_status == -1 && errno != EEXIST) { const char *error = strerror(errno); const wchar_t *errmsg = _(L"Unable to make a pipe for universal variables using '%ls': %s"); debug(0, errmsg, vars_path.c_str(), error); pipe_fd = -1; return; } int fd = wopen_cloexec(vars_path, O_RDWR | O_NONBLOCK, 0600); if (fd < 0) { const char *error = strerror(errno); const wchar_t *errmsg = _(L"Unable to open a pipe for universal variables using '%ls': %s"); debug(0, errmsg, vars_path.c_str(), error); pipe_fd = -1; return; } pipe_fd = fd; } #endif