#include "lazy.hh" #include "util.hh" #include "affinity.hh" #include "sync.hh" #include "finally.hh" #include "serialise.hh" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __APPLE__ #include #endif #ifdef __linux__ #include #endif extern char * * environ; namespace nix { const std::string nativeSystem = SYSTEM; BaseError & BaseError::addPrefix(const FormatOrString & fs) { prefix_ = fs.s + prefix_; return *this; } std::string SysError::addErrno(const std::string & s) { errNo = errno; return s + ": " + strerror(errNo); } std::optional getEnv(const std::string & key) { char * value = getenv(key.c_str()); if (!value) return {}; return std::string(value); } std::map getEnv() { std::map env; for (size_t i = 0; environ[i]; ++i) { auto s = environ[i]; auto eq = strchr(s, '='); if (!eq) // invalid env, just keep going continue; env.emplace(std::string(s, eq), std::string(eq + 1)); } return env; } void clearEnv() { for (auto & name : getEnv()) unsetenv(name.first.c_str()); } void replaceEnv(std::map newEnv) { clearEnv(); for (auto newEnvVar : newEnv) { setenv(newEnvVar.first.c_str(), newEnvVar.second.c_str(), 1); } } Path absPath(Path path, Path dir) { if (path[0] != '/') { if (dir == "") { #ifdef __GNU__ /* GNU (aka. GNU/Hurd) doesn't have any limitation on path lengths and doesn't define `PATH_MAX'. */ char *buf = getcwd(NULL, 0); if (buf == NULL) #else char buf[PATH_MAX]; if (!getcwd(buf, sizeof(buf))) #endif throw SysError("cannot get cwd"); dir = buf; #ifdef __GNU__ free(buf); #endif } path = dir + "/" + path; } return canonPath(path); } Path canonPath(const Path & path, bool resolveSymlinks) { assert(path != ""); string s; if (path[0] != '/') throw Error(format("not an absolute path: '%1%'") % path); string::const_iterator i = path.begin(), end = path.end(); string temp; /* Count the number of times we follow a symlink and stop at some arbitrary (but high) limit to prevent infinite loops. */ unsigned int followCount = 0, maxFollow = 1024; while (1) { /* Skip slashes. */ while (i != end && *i == '/') i++; if (i == end) break; /* Ignore `.'. */ if (*i == '.' && (i + 1 == end || i[1] == '/')) i++; /* If `..', delete the last component. */ else if (*i == '.' && i + 1 < end && i[1] == '.' && (i + 2 == end || i[2] == '/')) { if (!s.empty()) s.erase(s.rfind('/')); i += 2; } /* Normal component; copy it. */ else { s += '/'; while (i != end && *i != '/') s += *i++; /* If s points to a symlink, resolve it and restart (since the symlink target might contain new symlinks). */ if (resolveSymlinks && isLink(s)) { if (++followCount >= maxFollow) throw Error(format("infinite symlink recursion in path '%1%'") % path); temp = absPath(readLink(s), dirOf(s)) + string(i, end); i = temp.begin(); /* restart */ end = temp.end(); s = ""; } } } return s.empty() ? "/" : s; } Path dirOf(const Path & path) { Path::size_type pos = path.rfind('/'); if (pos == string::npos) return "."; return pos == 0 ? "/" : Path(path, 0, pos); } std::string_view baseNameOf(std::string_view path) { if (path.empty()) return ""; auto last = path.size() - 1; if (path[last] == '/' && last > 0) last -= 1; auto pos = path.rfind('/', last); if (pos == string::npos) pos = 0; else pos += 1; return path.substr(pos, last - pos + 1); } bool isInDir(const Path & path, const Path & dir) { return path[0] == '/' && string(path, 0, dir.size()) == dir && path.size() >= dir.size() + 2 && path[dir.size()] == '/'; } bool isDirOrInDir(const Path & path, const Path & dir) { return path == dir || isInDir(path, dir); } struct stat lstat(const Path & path) { struct stat st; if (lstat(path.c_str(), &st)) throw SysError(format("getting status of '%1%'") % path); return st; } bool pathExists(const Path & path) { int res; struct stat st; res = lstat(path.c_str(), &st); if (!res) return true; if (errno != ENOENT && errno != ENOTDIR) throw SysError(format("getting status of %1%") % path); return false; } Path readLink(const Path & path) { checkInterrupt(); std::vector buf; for (ssize_t bufSize = PATH_MAX/4; true; bufSize += bufSize/2) { buf.resize(bufSize); ssize_t rlSize = readlink(path.c_str(), buf.data(), bufSize); if (rlSize == -1) if (errno == EINVAL) throw Error("'%1%' is not a symlink", path); else throw SysError("reading symbolic link '%1%'", path); else if (rlSize < bufSize) return string(buf.data(), rlSize); } } bool isLink(const Path & path) { struct stat st = lstat(path); return S_ISLNK(st.st_mode); } DirEntries readDirectory(const Path & path) { DirEntries entries; entries.reserve(64); AutoCloseDir dir(opendir(path.c_str())); if (!dir) throw SysError(format("opening directory '%1%'") % path); struct dirent * dirent; while (errno = 0, dirent = readdir(dir.get())) { /* sic */ checkInterrupt(); string name = dirent->d_name; if (name == "." || name == "..") continue; entries.emplace_back(name, dirent->d_ino, #ifdef HAVE_STRUCT_DIRENT_D_TYPE dirent->d_type #else DT_UNKNOWN #endif ); } if (errno) throw SysError(format("reading directory '%1%'") % path); return entries; } unsigned char getFileType(const Path & path) { struct stat st = lstat(path); if (S_ISDIR(st.st_mode)) return DT_DIR; if (S_ISLNK(st.st_mode)) return DT_LNK; if (S_ISREG(st.st_mode)) return DT_REG; return DT_UNKNOWN; } string readFile(int fd) { struct stat st; if (fstat(fd, &st) == -1) throw SysError("statting file"); std::vector buf(st.st_size); readFull(fd, buf.data(), st.st_size); return string((char *) buf.data(), st.st_size); } string readFile(const Path & path, bool drain) { AutoCloseFD fd = open(path.c_str(), O_RDONLY | O_CLOEXEC); if (!fd) throw SysError(format("opening file '%1%'") % path); return drain ? drainFD(fd.get()) : readFile(fd.get()); } void readFile(const Path & path, Sink & sink) { AutoCloseFD fd = open(path.c_str(), O_RDONLY | O_CLOEXEC); if (!fd) throw SysError("opening file '%s'", path); drainFD(fd.get(), sink); } void writeFile(const Path & path, const string & s, mode_t mode) { AutoCloseFD fd = open(path.c_str(), O_WRONLY | O_TRUNC | O_CREAT | O_CLOEXEC, mode); if (!fd) throw SysError(format("opening file '%1%'") % path); writeFull(fd.get(), s); } void writeFile(const Path & path, Source & source, mode_t mode) { AutoCloseFD fd = open(path.c_str(), O_WRONLY | O_TRUNC | O_CREAT | O_CLOEXEC, mode); if (!fd) throw SysError(format("opening file '%1%'") % path); std::vector buf(64 * 1024); while (true) { try { auto n = source.read(buf.data(), buf.size()); writeFull(fd.get(), (unsigned char *) buf.data(), n); } catch (EndOfFile &) { break; } } } string readLine(int fd) { string s; while (1) { checkInterrupt(); char ch; // FIXME: inefficient ssize_t rd = read(fd, &ch, 1); if (rd == -1) { if (errno != EINTR) throw SysError("reading a line"); } else if (rd == 0) throw EndOfFile("unexpected EOF reading a line"); else { if (ch == '\n') return s; s += ch; } } } void writeLine(int fd, string s) { s += '\n'; writeFull(fd, s); } static void _deletePath(const Path & path, unsigned long long & bytesFreed) { checkInterrupt(); struct stat st; if (lstat(path.c_str(), &st) == -1) { if (errno == ENOENT) return; throw SysError(format("getting status of '%1%'") % path); } if (!S_ISDIR(st.st_mode) && st.st_nlink == 1) bytesFreed += st.st_size; if (S_ISDIR(st.st_mode)) { /* Make the directory accessible. */ const auto PERM_MASK = S_IRUSR | S_IWUSR | S_IXUSR; if ((st.st_mode & PERM_MASK) != PERM_MASK) { if (chmod(path.c_str(), st.st_mode | PERM_MASK) == -1) throw SysError(format("chmod '%1%'") % path); } for (auto & i : readDirectory(path)) _deletePath(path + "/" + i.name, bytesFreed); } if (remove(path.c_str()) == -1) { if (errno == ENOENT) return; throw SysError(format("cannot unlink '%1%'") % path); } } void deletePath(const Path & path) { unsigned long long dummy; deletePath(path, dummy); } void deletePath(const Path & path, unsigned long long & bytesFreed) { //Activity act(*logger, lvlDebug, format("recursively deleting path '%1%'") % path); bytesFreed = 0; _deletePath(path, bytesFreed); } static Path tempName(Path tmpRoot, const Path & prefix, bool includePid, int & counter) { tmpRoot = canonPath(tmpRoot.empty() ? getEnv("TMPDIR").value_or("/tmp") : tmpRoot, true); if (includePid) return (format("%1%/%2%-%3%-%4%") % tmpRoot % prefix % getpid() % counter++).str(); else return (format("%1%/%2%-%3%") % tmpRoot % prefix % counter++).str(); } Path createTempDir(const Path & tmpRoot, const Path & prefix, bool includePid, bool useGlobalCounter, mode_t mode) { static int globalCounter = 0; int localCounter = 0; int & counter(useGlobalCounter ? globalCounter : localCounter); while (1) { checkInterrupt(); Path tmpDir = tempName(tmpRoot, prefix, includePid, counter); if (mkdir(tmpDir.c_str(), mode) == 0) { #if __FreeBSD__ /* Explicitly set the group of the directory. This is to work around around problems caused by BSD's group ownership semantics (directories inherit the group of the parent). For instance, the group of /tmp on FreeBSD is "wheel", so all directories created in /tmp will be owned by "wheel"; but if the user is not in "wheel", then "tar" will fail to unpack archives that have the setgid bit set on directories. */ if (chown(tmpDir.c_str(), (uid_t) -1, getegid()) != 0) throw SysError(format("setting group of directory '%1%'") % tmpDir); #endif return tmpDir; } if (errno != EEXIST) throw SysError(format("creating directory '%1%'") % tmpDir); } } std::pair createTempFile(const Path & prefix) { Path tmpl(getEnv("TMPDIR").value_or("/tmp") + "/" + prefix + ".XXXXXX"); // Strictly speaking, this is UB, but who cares... AutoCloseFD fd(mkstemp((char *) tmpl.c_str())); if (!fd) throw SysError("creating temporary file '%s'", tmpl); return {std::move(fd), tmpl}; } std::string getUserName() { auto pw = getpwuid(geteuid()); std::string name = pw ? pw->pw_name : getEnv("USER").value_or(""); if (name.empty()) throw Error("cannot figure out user name"); return name; } static Lazy getHome2([]() { auto homeDir = getEnv("HOME"); if (!homeDir) { std::vector buf(16384); struct passwd pwbuf; struct passwd * pw; if (getpwuid_r(geteuid(), &pwbuf, buf.data(), buf.size(), &pw) != 0 || !pw || !pw->pw_dir || !pw->pw_dir[0]) throw Error("cannot determine user's home directory"); homeDir = pw->pw_dir; } return *homeDir; }); Path getHome() { return getHome2(); } Path getCacheDir() { auto cacheDir = getEnv("XDG_CACHE_HOME"); return cacheDir ? *cacheDir : getHome() + "/.cache"; } Path getConfigDir() { auto configDir = getEnv("XDG_CONFIG_HOME"); return configDir ? *configDir : getHome() + "/.config"; } std::vector getConfigDirs() { Path configHome = getConfigDir(); string configDirs = getEnv("XDG_CONFIG_DIRS").value_or(""); std::vector result = tokenizeString>(configDirs, ":"); result.insert(result.begin(), configHome); return result; } Path getDataDir() { auto dataDir = getEnv("XDG_DATA_HOME"); return dataDir ? *dataDir : getHome() + "/.local/share"; } Paths createDirs(const Path & path) { Paths created; if (path == "/") return created; struct stat st; if (lstat(path.c_str(), &st) == -1) { created = createDirs(dirOf(path)); if (mkdir(path.c_str(), 0777) == -1 && errno != EEXIST) throw SysError(format("creating directory '%1%'") % path); st = lstat(path); created.push_back(path); } if (S_ISLNK(st.st_mode) && stat(path.c_str(), &st) == -1) throw SysError(format("statting symlink '%1%'") % path); if (!S_ISDIR(st.st_mode)) throw Error(format("'%1%' is not a directory") % path); return created; } void createSymlink(const Path & target, const Path & link, std::optional mtime) { if (symlink(target.c_str(), link.c_str())) throw SysError(format("creating symlink from '%1%' to '%2%'") % link % target); if (mtime) { struct timeval times[2]; times[0].tv_sec = *mtime; times[0].tv_usec = 0; times[1].tv_sec = *mtime; times[1].tv_usec = 0; if (lutimes(link.c_str(), times)) throw SysError("setting time of symlink '%s'", link); } } void replaceSymlink(const Path & target, const Path & link, std::optional mtime) { for (unsigned int n = 0; true; n++) { Path tmp = canonPath(fmt("%s/.%d_%s", dirOf(link), n, baseNameOf(link))); try { createSymlink(target, tmp, mtime); } catch (SysError & e) { if (e.errNo == EEXIST) continue; throw; } if (rename(tmp.c_str(), link.c_str()) != 0) throw SysError(format("renaming '%1%' to '%2%'") % tmp % link); break; } } void readFull(int fd, unsigned char * buf, size_t count) { while (count) { checkInterrupt(); ssize_t res = read(fd, (char *) buf, count); if (res == -1) { if (errno == EINTR) continue; throw SysError("reading from file"); } if (res == 0) throw EndOfFile("unexpected end-of-file"); count -= res; buf += res; } } void writeFull(int fd, const unsigned char * buf, size_t count, bool allowInterrupts) { while (count) { if (allowInterrupts) checkInterrupt(); ssize_t res = write(fd, (char *) buf, count); if (res == -1 && errno != EINTR) throw SysError("writing to file"); if (res > 0) { count -= res; buf += res; } } } void writeFull(int fd, const string & s, bool allowInterrupts) { writeFull(fd, (const unsigned char *) s.data(), s.size(), allowInterrupts); } string drainFD(int fd, bool block) { StringSink sink; drainFD(fd, sink, block); return std::move(*sink.s); } void drainFD(int fd, Sink & sink, bool block) { int saved; Finally finally([&]() { if (!block) { if (fcntl(fd, F_SETFL, saved) == -1) throw SysError("making file descriptor blocking"); } }); if (!block) { saved = fcntl(fd, F_GETFL); if (fcntl(fd, F_SETFL, saved | O_NONBLOCK) == -1) throw SysError("making file descriptor non-blocking"); } std::vector buf(64 * 1024); while (1) { checkInterrupt(); ssize_t rd = read(fd, buf.data(), buf.size()); if (rd == -1) { if (!block && (errno == EAGAIN || errno == EWOULDBLOCK)) break; if (errno != EINTR) throw SysError("reading from file"); } else if (rd == 0) break; else sink(buf.data(), rd); } } ////////////////////////////////////////////////////////////////////// AutoDelete::AutoDelete() : del{false} {} AutoDelete::AutoDelete(const string & p, bool recursive) : path(p) { del = true; this->recursive = recursive; } AutoDelete::~AutoDelete() { try { if (del) { if (recursive) deletePath(path); else { if (remove(path.c_str()) == -1) throw SysError(format("cannot unlink '%1%'") % path); } } } catch (...) { ignoreException(); } } void AutoDelete::cancel() { del = false; } void AutoDelete::reset(const Path & p, bool recursive) { path = p; this->recursive = recursive; del = true; } ////////////////////////////////////////////////////////////////////// AutoCloseFD::AutoCloseFD() : fd{-1} {} AutoCloseFD::AutoCloseFD(int fd) : fd{fd} {} AutoCloseFD::AutoCloseFD(AutoCloseFD&& that) : fd{that.fd} { that.fd = -1; } AutoCloseFD& AutoCloseFD::operator =(AutoCloseFD&& that) { close(); fd = that.fd; that.fd = -1; return *this; } AutoCloseFD::~AutoCloseFD() { try { close(); } catch (...) { ignoreException(); } } int AutoCloseFD::get() const { return fd; } void AutoCloseFD::close() { if (fd != -1) { if (::close(fd) == -1) /* This should never happen. */ throw SysError(format("closing file descriptor %1%") % fd); } } AutoCloseFD::operator bool() const { return fd != -1; } int AutoCloseFD::release() { int oldFD = fd; fd = -1; return oldFD; } void Pipe::create() { int fds[2]; #if HAVE_PIPE2 if (pipe2(fds, O_CLOEXEC) != 0) throw SysError("creating pipe"); #else if (pipe(fds) != 0) throw SysError("creating pipe"); closeOnExec(fds[0]); closeOnExec(fds[1]); #endif readSide = fds[0]; writeSide = fds[1]; } ////////////////////////////////////////////////////////////////////// Pid::Pid() { } Pid::Pid(pid_t pid) : pid(pid) { } Pid::~Pid() { if (pid != -1) kill(); } void Pid::operator =(pid_t pid) { if (this->pid != -1 && this->pid != pid) kill(); this->pid = pid; killSignal = SIGKILL; // reset signal to default } Pid::operator pid_t() { return pid; } int Pid::kill() { assert(pid != -1); debug(format("killing process %1%") % pid); /* Send the requested signal to the child. If it has its own process group, send the signal to every process in the child process group (which hopefully includes *all* its children). */ if (::kill(separatePG ? -pid : pid, killSignal) != 0) { /* On BSDs, killing a process group will return EPERM if all processes in the group are zombies (or something like that). So try to detect and ignore that situation. */ #if __FreeBSD__ || __APPLE__ if (errno != EPERM || ::kill(pid, 0) != 0) #endif printError((SysError("killing process %d", pid).msg())); } return wait(); } int Pid::wait() { assert(pid != -1); while (1) { int status; int res = waitpid(pid, &status, 0); if (res == pid) { pid = -1; return status; } if (errno != EINTR) throw SysError("cannot get child exit status"); checkInterrupt(); } } void Pid::setSeparatePG(bool separatePG) { this->separatePG = separatePG; } void Pid::setKillSignal(int signal) { this->killSignal = signal; } pid_t Pid::release() { pid_t p = pid; pid = -1; return p; } void killUser(uid_t uid) { debug(format("killing all processes running under uid '%1%'") % uid); assert(uid != 0); /* just to be safe... */ /* The system call kill(-1, sig) sends the signal `sig' to all users to which the current process can send signals. So we fork a process, switch to uid, and send a mass kill. */ ProcessOptions options; options.allowVfork = false; Pid pid = startProcess([&]() { if (setuid(uid) == -1) throw SysError("setting uid"); while (true) { #ifdef __APPLE__ /* OSX's kill syscall takes a third parameter that, among other things, determines if kill(-1, signo) affects the calling process. In the OSX libc, it's set to true, which means "follow POSIX", which we don't want here */ if (syscall(SYS_kill, -1, SIGKILL, false) == 0) break; #else if (kill(-1, SIGKILL) == 0) break; #endif if (errno == ESRCH) break; /* no more processes */ if (errno != EINTR) throw SysError(format("cannot kill processes for uid '%1%'") % uid); } _exit(0); }, options); int status = pid.wait(); if (status != 0) throw Error(format("cannot kill processes for uid '%1%': %2%") % uid % statusToString(status)); /* !!! We should really do some check to make sure that there are no processes left running under `uid', but there is no portable way to do so (I think). The most reliable way may be `ps -eo uid | grep -q $uid'. */ } ////////////////////////////////////////////////////////////////////// /* Wrapper around vfork to prevent the child process from clobbering the caller's stack frame in the parent. */ static pid_t doFork(bool allowVfork, std::function fun) __attribute__((noinline)); static pid_t doFork(bool allowVfork, std::function fun) { #ifdef __linux__ pid_t pid = allowVfork ? vfork() : fork(); #else pid_t pid = fork(); #endif if (pid != 0) return pid; fun(); abort(); } pid_t startProcess(std::function fun, const ProcessOptions & options) { auto wrapper = [&]() { if (!options.allowVfork) logger = makeDefaultLogger(); try { #if __linux__ if (options.dieWithParent && prctl(PR_SET_PDEATHSIG, SIGKILL) == -1) throw SysError("setting death signal"); #endif restoreAffinity(); fun(); } catch (std::exception & e) { try { std::cerr << options.errorPrefix << e.what() << "\n"; } catch (...) { } } catch (...) { } if (options.runExitHandlers) exit(1); else _exit(1); }; pid_t pid = doFork(options.allowVfork, wrapper); if (pid == -1) throw SysError("unable to fork"); return pid; } std::vector stringsToCharPtrs(const Strings & ss) { std::vector res; for (auto & s : ss) res.push_back((char *) s.c_str()); res.push_back(0); return res; } // Output = "standard out" output stream string runProgram(Path program, bool searchPath, const Strings & args, const std::optional & input) { RunOptions opts(program, args); opts.searchPath = searchPath; // This allows you to refer to a program with a pathname relative to the // PATH variable. opts.input = input; auto res = runProgram(opts); if (!statusOk(res.first)) throw ExecError(res.first, fmt("program '%1%' %2%", program, statusToString(res.first))); return res.second; } // Output = error code + "standard out" output stream std::pair runProgram(const RunOptions & options_) { RunOptions options(options_); StringSink sink; options.standardOut = &sink; int status = 0; try { runProgram2(options); } catch (ExecError & e) { status = e.status; } return {status, std::move(*sink.s)}; } void runProgram2(const RunOptions & options) { checkInterrupt(); assert(!(options.standardIn && options.input)); std::unique_ptr source_; Source * source = options.standardIn; if (options.input) { source_ = std::make_unique(*options.input); source = source_.get(); } /* Create a pipe. */ Pipe out, in; if (options.standardOut) out.create(); if (source) in.create(); ProcessOptions processOptions; // vfork implies that the environment of the main process and the fork will // be shared (technically this is undefined, but in practice that's the // case), so we can't use it if we alter the environment if (options.environment) processOptions.allowVfork = false; /* Fork. */ Pid pid = startProcess([&]() { if (options.environment) replaceEnv(*options.environment); if (options.standardOut && dup2(out.writeSide.get(), STDOUT_FILENO) == -1) throw SysError("dupping stdout"); if (options.mergeStderrToStdout) if (dup2(STDOUT_FILENO, STDERR_FILENO) == -1) throw SysError("cannot dup stdout into stderr"); if (source && dup2(in.readSide.get(), STDIN_FILENO) == -1) throw SysError("dupping stdin"); if (options.chdir && chdir((*options.chdir).c_str()) == -1) throw SysError("chdir failed"); if (options.gid && setgid(*options.gid) == -1) throw SysError("setgid failed"); /* Drop all other groups if we're setgid. */ if (options.gid && setgroups(0, 0) == -1) throw SysError("setgroups failed"); if (options.uid && setuid(*options.uid) == -1) throw SysError("setuid failed"); Strings args_(options.args); args_.push_front(options.program); restoreSignals(); if (options.searchPath) execvp(options.program.c_str(), stringsToCharPtrs(args_).data()); // This allows you to refer to a program with a pathname relative // to the PATH variable. else execv(options.program.c_str(), stringsToCharPtrs(args_).data()); throw SysError("executing '%1%'", options.program); }, processOptions); out.writeSide = -1; std::thread writerThread; std::promise promise; Finally doJoin([&]() { if (writerThread.joinable()) writerThread.join(); }); if (source) { in.readSide = -1; writerThread = std::thread([&]() { try { std::vector buf(8 * 1024); while (true) { size_t n; try { n = source->read(buf.data(), buf.size()); } catch (EndOfFile &) { break; } writeFull(in.writeSide.get(), buf.data(), n); } promise.set_value(); } catch (...) { promise.set_exception(std::current_exception()); } in.writeSide = -1; }); } if (options.standardOut) drainFD(out.readSide.get(), *options.standardOut); /* Wait for the child to finish. */ int status = pid.wait(); /* Wait for the writer thread to finish. */ if (source) promise.get_future().get(); if (status) throw ExecError(status, fmt("program '%1%' %2%", options.program, statusToString(status))); } void closeMostFDs(const set & exceptions) { #if __linux__ try { for (auto & s : readDirectory("/proc/self/fd")) { auto fd = std::stoi(s.name); if (!exceptions.count(fd)) { debug("closing leaked FD %d", fd); close(fd); } } return; } catch (SysError &) { } #endif int maxFD = 0; maxFD = sysconf(_SC_OPEN_MAX); for (int fd = 0; fd < maxFD; ++fd) if (!exceptions.count(fd)) close(fd); /* ignore result */ } void closeOnExec(int fd) { int prev; if ((prev = fcntl(fd, F_GETFD, 0)) == -1 || fcntl(fd, F_SETFD, prev | FD_CLOEXEC) == -1) throw SysError("setting close-on-exec flag"); } ////////////////////////////////////////////////////////////////////// bool _isInterrupted = false; static thread_local bool interruptThrown = false; thread_local std::function interruptCheck; void setInterruptThrown() { interruptThrown = true; } void _interrupted() { /* Block user interrupts while an exception is being handled. Throwing an exception while another exception is being handled kills the program! */ if (!interruptThrown && !std::uncaught_exception()) { interruptThrown = true; throw Interrupted("interrupted by the user"); } } ////////////////////////////////////////////////////////////////////// template C tokenizeString(const string & s, const string & separators) { C result; string::size_type pos = s.find_first_not_of(separators, 0); while (pos != string::npos) { string::size_type end = s.find_first_of(separators, pos + 1); if (end == string::npos) end = s.size(); string token(s, pos, end - pos); result.insert(result.end(), token); pos = s.find_first_not_of(separators, end); } return result; } template Strings tokenizeString(const string & s, const string & separators); template StringSet tokenizeString(const string & s, const string & separators); template vector tokenizeString(const string & s, const string & separators); string chomp(const string & s) { size_t i = s.find_last_not_of(" \n\r\t"); return i == string::npos ? "" : string(s, 0, i + 1); } string trim(const string & s, const string & whitespace) { auto i = s.find_first_not_of(whitespace); if (i == string::npos) return ""; auto j = s.find_last_not_of(whitespace); return string(s, i, j == string::npos ? j : j - i + 1); } string replaceStrings(const std::string & s, const std::string & from, const std::string & to) { if (from.empty()) return s; string res = s; size_t pos = 0; while ((pos = res.find(from, pos)) != std::string::npos) { res.replace(pos, from.size(), to); pos += to.size(); } return res; } std::string rewriteStrings(const std::string & _s, const StringMap & rewrites) { auto s = _s; for (auto & i : rewrites) { if (i.first == i.second) continue; size_t j = 0; while ((j = s.find(i.first, j)) != string::npos) s.replace(j, i.first.size(), i.second); } return s; } string statusToString(int status) { if (!WIFEXITED(status) || WEXITSTATUS(status) != 0) { if (WIFEXITED(status)) return (format("failed with exit code %1%") % WEXITSTATUS(status)).str(); else if (WIFSIGNALED(status)) { int sig = WTERMSIG(status); #if HAVE_STRSIGNAL const char * description = strsignal(sig); return (format("failed due to signal %1% (%2%)") % sig % description).str(); #else return (format("failed due to signal %1%") % sig).str(); #endif } else return "died abnormally"; } else return "succeeded"; } bool statusOk(int status) { return WIFEXITED(status) && WEXITSTATUS(status) == 0; } bool hasPrefix(const string & s, const string & prefix) { return s.compare(0, prefix.size(), prefix) == 0; } bool hasSuffix(std::string_view s, std::string_view suffix) { return s.size() >= suffix.size() && s.substr(s.size() - suffix.size()) == suffix; } std::string toLower(const std::string & s) { std::string r(s); for (auto & c : r) c = std::tolower(c); return r; } std::string shellEscape(const std::string & s) { std::string r = "'"; for (auto & i : s) if (i == '\'') r += "'\\''"; else r += i; r += '\''; return r; } void ignoreException() { try { throw; } catch (std::exception & e) { printError(format("error (ignored): %1%") % e.what()); } } std::string filterANSIEscapes(const std::string & s, bool filterAll, unsigned int width) { std::string t, e; size_t w = 0; auto i = s.begin(); while (w < (size_t) width && i != s.end()) { if (*i == '\e') { std::string e; e += *i++; char last = 0; if (i != s.end() && *i == '[') { e += *i++; // eat parameter bytes while (i != s.end() && *i >= 0x30 && *i <= 0x3f) e += *i++; // eat intermediate bytes while (i != s.end() && *i >= 0x20 && *i <= 0x2f) e += *i++; // eat final byte if (i != s.end() && *i >= 0x40 && *i <= 0x7e) e += last = *i++; } else { if (i != s.end() && *i >= 0x40 && *i <= 0x5f) e += *i++; } if (!filterAll && last == 'm') t += e; } else if (*i == '\t') { i++; t += ' '; w++; while (w < (size_t) width && w % 8) { t += ' '; w++; } } else if (*i == '\r') // do nothing for now i++; else { t += *i++; w++; } } return t; } static char base64Chars[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/"; string base64Encode(const string & s) { string res; int data = 0, nbits = 0; for (char c : s) { data = data << 8 | (unsigned char) c; nbits += 8; while (nbits >= 6) { nbits -= 6; res.push_back(base64Chars[data >> nbits & 0x3f]); } } if (nbits) res.push_back(base64Chars[data << (6 - nbits) & 0x3f]); while (res.size() % 4) res.push_back('='); return res; } string base64Decode(const string & s) { bool init = false; char decode[256]; if (!init) { // FIXME: not thread-safe. memset(decode, -1, sizeof(decode)); for (int i = 0; i < 64; i++) decode[(int) base64Chars[i]] = i; init = true; } string res; unsigned int d = 0, bits = 0; for (char c : s) { if (c == '=') break; if (c == '\n') continue; char digit = decode[(unsigned char) c]; if (digit == -1) throw Error("invalid character in Base64 string"); bits += 6; d = d << 6 | digit; if (bits >= 8) { res.push_back(d >> (bits - 8) & 0xff); bits -= 8; } } return res; } void callFailure(const std::function & failure, std::exception_ptr exc) { try { failure(exc); } catch (std::exception & e) { printError(format("uncaught exception: %s") % e.what()); abort(); } } static Sync> windowSize{{0, 0}}; static void updateWindowSize() { struct winsize ws; if (ioctl(2, TIOCGWINSZ, &ws) == 0) { auto windowSize_(windowSize.lock()); windowSize_->first = ws.ws_row; windowSize_->second = ws.ws_col; } } std::pair getWindowSize() { return *windowSize.lock(); } static Sync>> _interruptCallbacks; static void signalHandlerThread(sigset_t set) { while (true) { int signal = 0; sigwait(&set, &signal); if (signal == SIGINT || signal == SIGTERM || signal == SIGHUP) triggerInterrupt(); else if (signal == SIGWINCH) { updateWindowSize(); } } } void triggerInterrupt() { _isInterrupted = true; { auto interruptCallbacks(_interruptCallbacks.lock()); for (auto & callback : *interruptCallbacks) { try { callback(); } catch (...) { ignoreException(); } } } } static sigset_t savedSignalMask; void startSignalHandlerThread() { updateWindowSize(); if (sigprocmask(SIG_BLOCK, nullptr, &savedSignalMask)) throw SysError("quering signal mask"); sigset_t set; sigemptyset(&set); sigaddset(&set, SIGINT); sigaddset(&set, SIGTERM); sigaddset(&set, SIGHUP); sigaddset(&set, SIGPIPE); sigaddset(&set, SIGWINCH); if (pthread_sigmask(SIG_BLOCK, &set, nullptr)) throw SysError("blocking signals"); std::thread(signalHandlerThread, set).detach(); } void restoreSignals() { if (sigprocmask(SIG_SETMASK, &savedSignalMask, nullptr)) throw SysError("restoring signals"); } /* RAII helper to automatically deregister a callback. */ struct InterruptCallbackImpl : InterruptCallback { std::list>::iterator it; ~InterruptCallbackImpl() override { _interruptCallbacks.lock()->erase(it); } }; std::unique_ptr createInterruptCallback(std::function callback) { auto interruptCallbacks(_interruptCallbacks.lock()); interruptCallbacks->push_back(callback); auto res = std::make_unique(); res->it = interruptCallbacks->end(); res->it--; return std::unique_ptr(res.release()); } AutoCloseFD createUnixDomainSocket(const Path & path, mode_t mode) { AutoCloseFD fdSocket = socket(PF_UNIX, SOCK_STREAM #ifdef SOCK_CLOEXEC | SOCK_CLOEXEC #endif , 0); if (!fdSocket) throw SysError("cannot create Unix domain socket"); closeOnExec(fdSocket.get()); struct sockaddr_un addr; addr.sun_family = AF_UNIX; if (path.size() >= sizeof(addr.sun_path)) throw Error("socket path '%1%' is too long", path); strcpy(addr.sun_path, path.c_str()); unlink(path.c_str()); if (bind(fdSocket.get(), (struct sockaddr *) &addr, sizeof(addr)) == -1) throw SysError("cannot bind to socket '%1%'", path); if (chmod(path.c_str(), mode) == -1) throw SysError("changing permissions on '%1%'", path); if (listen(fdSocket.get(), 5) == -1) throw SysError("cannot listen on socket '%1%'", path); return fdSocket; } }