//===--------------------- filesystem/ops.cpp -----------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "experimental/filesystem" #include "iterator" #include "fstream" #include "type_traits" #include "random" /* for unique_path */ #include "cstdlib" #include "climits" #include #include #include #include /* values for fchmodat */ #if !defined(UTIME_OMIT) #include // for ::utimes as used in __last_write_time #endif _LIBCPP_BEGIN_NAMESPACE_EXPERIMENTAL_FILESYSTEM filesystem_error::~filesystem_error() {} // POSIX HELPERS namespace detail { namespace { using value_type = path::value_type; using string_type = path::string_type; inline std::error_code capture_errno() { _LIBCPP_ASSERT(errno, "Expected errno to be non-zero"); return std::error_code(errno, std::generic_category()); } void set_or_throw(std::error_code const& m_ec, std::error_code* ec, const char* msg, path const& p = {}, path const& p2 = {}) { if (ec) { *ec = m_ec; } else { string msg_s("std::experimental::filesystem::"); msg_s += msg; __throw_filesystem_error(msg_s, p, p2, m_ec); } } void set_or_throw(std::error_code* ec, const char* msg, path const& p = {}, path const& p2 = {}) { return set_or_throw(capture_errno(), ec, msg, p, p2); } perms posix_get_perms(const struct ::stat & st) noexcept { return static_cast(st.st_mode) & perms::mask; } ::mode_t posix_convert_perms(perms prms) { return static_cast< ::mode_t>(prms & perms::mask); } file_status create_file_status(std::error_code& m_ec, path const& p, struct ::stat& path_stat, std::error_code* ec) { if (ec) *ec = m_ec; if (m_ec && (m_ec.value() == ENOENT || m_ec.value() == ENOTDIR)) { return file_status(file_type::not_found); } else if (m_ec) { set_or_throw(m_ec, ec, "posix_stat", p); return file_status(file_type::none); } // else file_status fs_tmp; auto const mode = path_stat.st_mode; if (S_ISLNK(mode)) fs_tmp.type(file_type::symlink); else if (S_ISREG(mode)) fs_tmp.type(file_type::regular); else if (S_ISDIR(mode)) fs_tmp.type(file_type::directory); else if (S_ISBLK(mode)) fs_tmp.type(file_type::block); else if (S_ISCHR(mode)) fs_tmp.type(file_type::character); else if (S_ISFIFO(mode)) fs_tmp.type(file_type::fifo); else if (S_ISSOCK(mode)) fs_tmp.type(file_type::socket); else fs_tmp.type(file_type::unknown); fs_tmp.permissions(detail::posix_get_perms(path_stat)); return fs_tmp; } file_status posix_stat(path const & p, struct ::stat& path_stat, std::error_code* ec) { std::error_code m_ec; if (::stat(p.c_str(), &path_stat) == -1) m_ec = detail::capture_errno(); return create_file_status(m_ec, p, path_stat, ec); } file_status posix_stat(path const & p, std::error_code* ec) { struct ::stat path_stat; return posix_stat(p, path_stat, ec); } file_status posix_lstat(path const & p, struct ::stat & path_stat, std::error_code* ec) { std::error_code m_ec; if (::lstat(p.c_str(), &path_stat) == -1) m_ec = detail::capture_errno(); return create_file_status(m_ec, p, path_stat, ec); } file_status posix_lstat(path const & p, std::error_code* ec) { struct ::stat path_stat; return posix_lstat(p, path_stat, ec); } bool stat_equivalent(struct ::stat& st1, struct ::stat& st2) { return (st1.st_dev == st2.st_dev && st1.st_ino == st2.st_ino); } // DETAIL::MISC bool copy_file_impl(const path& from, const path& to, perms from_perms, std::error_code *ec) { std::ifstream in(from.c_str(), std::ios::binary); std::ofstream out(to.c_str(), std::ios::binary); if (in.good() && out.good()) { using InIt = std::istreambuf_iterator; using OutIt = std::ostreambuf_iterator; InIt bin(in); InIt ein; OutIt bout(out); std::copy(bin, ein, bout); } if (out.fail() || in.fail()) { set_or_throw(make_error_code(errc::operation_not_permitted), ec, "copy_file", from, to); return false; } __permissions(to, from_perms, ec); // TODO what if permissions fails? return true; } }} // end namespace detail using detail::set_or_throw; path __canonical(path const & orig_p, const path& base, std::error_code *ec) { path p = absolute(orig_p, base); char buff[PATH_MAX + 1]; char *ret; if ((ret = ::realpath(p.c_str(), buff)) == nullptr) { set_or_throw(ec, "canonical", orig_p, base); return {}; } if (ec) ec->clear(); return {ret}; } void __copy(const path& from, const path& to, copy_options options, std::error_code *ec) { const bool sym_status = bool(options & (copy_options::create_symlinks | copy_options::skip_symlinks)); const bool sym_status2 = bool(options & copy_options::copy_symlinks); std::error_code m_ec; struct ::stat f_st = {}; const file_status f = sym_status || sym_status2 ? detail::posix_lstat(from, f_st, &m_ec) : detail::posix_stat(from, f_st, &m_ec); if (m_ec) return set_or_throw(m_ec, ec, "copy", from, to); struct ::stat t_st = {}; const file_status t = sym_status ? detail::posix_lstat(to, t_st, &m_ec) : detail::posix_stat(to, t_st, &m_ec); if (not status_known(t)) return set_or_throw(m_ec, ec, "copy", from, to); if (!exists(f) || is_other(f) || is_other(t) || (is_directory(f) && is_regular_file(t)) || detail::stat_equivalent(f_st, t_st)) { return set_or_throw(make_error_code(errc::function_not_supported), ec, "copy", from, to); } if (ec) ec->clear(); if (is_symlink(f)) { if (bool(copy_options::skip_symlinks & options)) { // do nothing } else if (not exists(t)) { __copy_symlink(from, to, ec); } else { set_or_throw(make_error_code(errc::file_exists), ec, "copy", from, to); } return; } else if (is_regular_file(f)) { if (bool(copy_options::directories_only & options)) { // do nothing } else if (bool(copy_options::create_symlinks & options)) { __create_symlink(from, to, ec); } else if (bool(copy_options::create_hard_links & options)) { __create_hard_link(from, to, ec); } else if (is_directory(t)) { __copy_file(from, to / from.filename(), options, ec); } else { __copy_file(from, to, options, ec); } return; } else if (is_directory(f) && bool(copy_options::create_symlinks & options)) { return set_or_throw(make_error_code(errc::is_a_directory), ec, "copy"); } else if (is_directory(f) && (bool(copy_options::recursive & options) || copy_options::none == options)) { if (!exists(t)) { // create directory to with attributes from 'from'. __create_directory(to, from, ec); if (ec && *ec) { return; } } directory_iterator it = ec ? directory_iterator(from, *ec) : directory_iterator(from); if (ec && *ec) { return; } std::error_code m_ec; for (; it != directory_iterator(); it.increment(m_ec)) { if (m_ec) return set_or_throw(m_ec, ec, "copy", from, to); __copy(it->path(), to / it->path().filename(), options | copy_options::__in_recursive_copy, ec); if (ec && *ec) { return; } } } } bool __copy_file(const path& from, const path& to, copy_options options, std::error_code *ec) { if (ec) ec->clear(); std::error_code m_ec; auto from_st = detail::posix_stat(from, &m_ec); if (not is_regular_file(from_st)) { if (not m_ec) m_ec = make_error_code(errc::not_supported); set_or_throw(m_ec, ec, "copy_file", from, to); return false; } auto to_st = detail::posix_stat(to, &m_ec); if (!status_known(to_st)) { set_or_throw(m_ec, ec, "copy_file", from, to); return false; } const bool to_exists = exists(to_st); if (to_exists && !is_regular_file(to_st)) { set_or_throw(make_error_code(errc::not_supported), ec, "copy_file", from, to); return false; } if (to_exists && bool(copy_options::skip_existing & options)) { return false; } else if (to_exists && bool(copy_options::update_existing & options)) { auto from_time = __last_write_time(from, ec); if (ec && *ec) { return false; } auto to_time = __last_write_time(to, ec); if (ec && *ec) { return false; } if (from_time <= to_time) { return false; } return detail::copy_file_impl(from, to, from_st.permissions(), ec); } else if (!to_exists || bool(copy_options::overwrite_existing & options)) { return detail::copy_file_impl(from, to, from_st.permissions(), ec); } else { set_or_throw(make_error_code(errc::file_exists), ec, "copy", from, to); return false; } _LIBCPP_UNREACHABLE(); } void __copy_symlink(const path& existing_symlink, const path& new_symlink, std::error_code *ec) { const path real_path(__read_symlink(existing_symlink, ec)); if (ec && *ec) { return; } // NOTE: proposal says you should detect if you should call // create_symlink or create_directory_symlink. I don't think this // is needed with POSIX __create_symlink(real_path, new_symlink, ec); } bool __create_directories(const path& p, std::error_code *ec) { std::error_code m_ec; auto const st = detail::posix_stat(p, &m_ec); if (!status_known(st)) { set_or_throw(m_ec, ec, "create_directories", p); return false; } else if (is_directory(st)) { if (ec) ec->clear(); return false; } else if (exists(st)) { set_or_throw(make_error_code(errc::file_exists), ec, "create_directories", p); return false; } const path parent = p.parent_path(); if (!parent.empty()) { const file_status parent_st = status(parent, m_ec); if (not status_known(parent_st)) { set_or_throw(m_ec, ec, "create_directories", p); return false; } if (not exists(parent_st)) { __create_directories(parent, ec); if (ec && *ec) { return false; } } } return __create_directory(p, ec); } bool __create_directory(const path& p, std::error_code *ec) { if (ec) ec->clear(); if (::mkdir(p.c_str(), static_cast(perms::all)) == 0) return true; if (errno != EEXIST || !is_directory(p)) set_or_throw(ec, "create_directory", p); return false; } bool __create_directory(path const & p, path const & attributes, std::error_code *ec) { struct ::stat attr_stat; std::error_code mec; auto st = detail::posix_stat(attributes, attr_stat, &mec); if (!status_known(st)) { set_or_throw(mec, ec, "create_directory", p, attributes); return false; } if (ec) ec->clear(); if (::mkdir(p.c_str(), attr_stat.st_mode) == 0) return true; if (errno != EEXIST || !is_directory(p)) set_or_throw(ec, "create_directory", p, attributes); return false; } void __create_directory_symlink(path const & from, path const & to, std::error_code *ec){ if (::symlink(from.c_str(), to.c_str()) != 0) set_or_throw(ec, "create_directory_symlink", from, to); else if (ec) ec->clear(); } void __create_hard_link(const path& from, const path& to, std::error_code *ec){ if (::link(from.c_str(), to.c_str()) == -1) set_or_throw(ec, "create_hard_link", from, to); else if (ec) ec->clear(); } void __create_symlink(path const & from, path const & to, std::error_code *ec) { if (::symlink(from.c_str(), to.c_str()) == -1) set_or_throw(ec, "create_symlink", from, to); else if (ec) ec->clear(); } path __current_path(std::error_code *ec) { auto size = ::pathconf(".", _PC_PATH_MAX); _LIBCPP_ASSERT(size >= 0, "pathconf returned a 0 as max size"); auto buff = std::unique_ptr(new char[size + 1]); char* ret; if ((ret = ::getcwd(buff.get(), static_cast(size))) == nullptr) { set_or_throw(ec, "current_path"); return {}; } if (ec) ec->clear(); return {buff.get()}; } void __current_path(const path& p, std::error_code *ec) { if (::chdir(p.c_str()) == -1) set_or_throw(ec, "current_path", p); else if (ec) ec->clear(); } bool __equivalent(const path& p1, const path& p2, std::error_code *ec) { std::error_code ec1, ec2; struct ::stat st1 = {}; struct ::stat st2 = {}; auto s1 = detail::posix_stat(p1.native(), st1, &ec1); auto s2 = detail::posix_stat(p2.native(), st2, &ec2); if ((!exists(s1) && !exists(s2)) || (is_other(s1) && is_other(s2))) { set_or_throw(make_error_code(errc::not_supported), ec, "equivalent", p1, p2); return false; } if (ec) ec->clear(); return (st1.st_dev == st2.st_dev && st1.st_ino == st2.st_ino); } std::uintmax_t __file_size(const path& p, std::error_code *ec) { std::error_code m_ec; struct ::stat st; file_status fst = detail::posix_stat(p, st, &m_ec); if (!exists(fst) || !is_regular_file(fst)) { if (!m_ec) m_ec = make_error_code(errc::not_supported); set_or_throw(m_ec, ec, "file_size", p); return static_cast(-1); } // is_regular_file(p) == true if (ec) ec->clear(); return static_cast(st.st_size); } std::uintmax_t __hard_link_count(const path& p, std::error_code *ec) { std::error_code m_ec; struct ::stat st; detail::posix_stat(p, st, &m_ec); if (m_ec) { set_or_throw(m_ec, ec, "hard_link_count", p); return static_cast(-1); } if (ec) ec->clear(); return static_cast(st.st_nlink); } bool __fs_is_empty(const path& p, std::error_code *ec) { if (ec) ec->clear(); std::error_code m_ec; struct ::stat pst; auto st = detail::posix_stat(p, pst, &m_ec); if (m_ec) { set_or_throw(m_ec, ec, "is_empty", p); return false; } else if (!is_directory(st) && !is_regular_file(st)) { m_ec = make_error_code(errc::not_supported); set_or_throw(m_ec, ec, "is_empty"); return false; } else if (is_directory(st)) { auto it = ec ? directory_iterator(p, *ec) : directory_iterator(p); if (ec && *ec) return false; return it == directory_iterator{}; } else if (is_regular_file(st)) return static_cast(pst.st_size) == 0; _LIBCPP_UNREACHABLE(); } namespace detail { namespace { using namespace std::chrono; template bool checked_set(CType* out, ChronoType time) { using Lim = numeric_limits; if (time > Lim::max() || time < Lim::min()) return false; *out = static_cast(time); return true; } using TimeSpec = struct ::timespec; using StatT = struct ::stat; #if defined(__APPLE__) TimeSpec extract_mtime(StatT const& st) { return st.st_mtimespec; } TimeSpec extract_atime(StatT const& st) { return st.st_atimespec; } #else TimeSpec extract_mtime(StatT const& st) { return st.st_mtim; } __attribute__((unused)) // Suppress warning TimeSpec extract_atime(StatT const& st) { return st.st_atim; } #endif constexpr auto max_seconds = duration_cast( file_time_type::duration::max()).count(); constexpr auto max_nsec = duration_cast( file_time_type::duration::max() - seconds(max_seconds)).count(); constexpr auto min_seconds = duration_cast( file_time_type::duration::min()).count(); constexpr auto min_nsec_timespec = duration_cast( (file_time_type::duration::min() - seconds(min_seconds)) + seconds(1)).count(); // Static assert that these values properly round trip. static_assert((seconds(min_seconds) + duration_cast(nanoseconds(min_nsec_timespec))) - duration_cast(seconds(1)) == file_time_type::duration::min(), ""); constexpr auto max_time_t = numeric_limits::max(); constexpr auto min_time_t = numeric_limits::min(); #if !defined(__LP64__) && defined(__clang__) #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wtautological-constant-out-of-range-compare" #endif _LIBCPP_CONSTEXPR_AFTER_CXX11 bool is_representable(TimeSpec const& tm) { if (tm.tv_sec >= 0) { return (tm.tv_sec < max_seconds) || (tm.tv_sec == max_seconds && tm.tv_nsec <= max_nsec); } else if (tm.tv_sec == (min_seconds - 1)) { return tm.tv_nsec >= min_nsec_timespec; } else { return (tm.tv_sec >= min_seconds); } } #ifndef _LIBCPP_HAS_NO_CXX14_CONSTEXPR #if defined(__LP64__) static_assert(is_representable({max_seconds, max_nsec}), ""); static_assert(!is_representable({max_seconds + 1, 0}), ""); static_assert(!is_representable({max_seconds, max_nsec + 1}), ""); static_assert(!is_representable({max_time_t, 0}), ""); static_assert(is_representable({min_seconds, 0}), ""); static_assert(is_representable({min_seconds - 1, min_nsec_timespec}), ""); static_assert(is_representable({min_seconds - 1, min_nsec_timespec + 1}), ""); static_assert(!is_representable({min_seconds - 1, min_nsec_timespec - 1}), ""); static_assert(!is_representable({min_time_t, 999999999}), ""); #else static_assert(is_representable({max_time_t, 999999999}), ""); static_assert(is_representable({max_time_t, 1000000000}), ""); static_assert(is_representable({min_time_t, 0}), ""); #endif #endif _LIBCPP_CONSTEXPR_AFTER_CXX11 bool is_representable(file_time_type const& tm) { auto secs = duration_cast(tm.time_since_epoch()); auto nsecs = duration_cast(tm.time_since_epoch() - secs); if (nsecs.count() < 0) { secs = secs + seconds(1); nsecs = nsecs + seconds(1); } using TLim = numeric_limits; if (secs.count() >= 0) return secs.count() <= TLim::max(); return secs.count() >= TLim::min(); } #ifndef _LIBCPP_HAS_NO_CXX14_CONSTEXPR #if defined(__LP64__) static_assert(is_representable(file_time_type::max()), ""); static_assert(is_representable(file_time_type::min()), ""); #else static_assert(!is_representable(file_time_type::max()), ""); static_assert(!is_representable(file_time_type::min()), ""); static_assert(is_representable(file_time_type(seconds(max_time_t))), ""); static_assert(is_representable(file_time_type(seconds(min_time_t))), ""); #endif #endif _LIBCPP_CONSTEXPR_AFTER_CXX11 file_time_type convert_timespec(TimeSpec const& tm) { auto adj_msec = duration_cast(nanoseconds(tm.tv_nsec)); if (tm.tv_sec >= 0) { auto Dur = seconds(tm.tv_sec) + microseconds(adj_msec); return file_time_type(Dur); } else if (duration_cast(nanoseconds(tm.tv_nsec)).count() == 0) { return file_time_type(seconds(tm.tv_sec)); } else { // tm.tv_sec < 0 auto adj_subsec = duration_cast(seconds(1) - nanoseconds(tm.tv_nsec)); auto Dur = seconds(tm.tv_sec + 1) - adj_subsec; return file_time_type(Dur); } } #ifndef _LIBCPP_HAS_NO_CXX14_CONSTEXPR #if defined(__LP64__) static_assert(convert_timespec({max_seconds, max_nsec}) == file_time_type::max(), ""); static_assert(convert_timespec({max_seconds, max_nsec - 1}) < file_time_type::max(), ""); static_assert(convert_timespec({max_seconds - 1, 999999999}) < file_time_type::max(), ""); static_assert(convert_timespec({min_seconds - 1, min_nsec_timespec}) == file_time_type::min(), ""); static_assert(convert_timespec({min_seconds - 1, min_nsec_timespec + 1}) > file_time_type::min(), ""); static_assert(convert_timespec({min_seconds , 0}) > file_time_type::min(), ""); #else // FIXME add tests for 32 bit builds #endif #endif #if !defined(__LP64__) && defined(__clang__) #pragma clang diagnostic pop #endif template bool set_times_checked(time_t* sec_out, SubSecT* subsec_out, file_time_type tp) { using namespace chrono; auto dur = tp.time_since_epoch(); auto sec_dur = duration_cast(dur); auto subsec_dur = duration_cast(dur - sec_dur); // The tv_nsec and tv_usec fields must not be negative so adjust accordingly if (subsec_dur.count() < 0) { if (sec_dur.count() > min_seconds) { sec_dur -= seconds(1); subsec_dur += seconds(1); } else { subsec_dur = SubSecDurT::zero(); } } return checked_set(sec_out, sec_dur.count()) && checked_set(subsec_out, subsec_dur.count()); } }} // end namespace detail file_time_type __last_write_time(const path& p, std::error_code *ec) { using namespace ::std::chrono; std::error_code m_ec; struct ::stat st; detail::posix_stat(p, st, &m_ec); if (m_ec) { set_or_throw(m_ec, ec, "last_write_time", p); return file_time_type::min(); } if (ec) ec->clear(); auto ts = detail::extract_mtime(st); if (!detail::is_representable(ts)) { set_or_throw(error_code(EOVERFLOW, generic_category()), ec, "last_write_time", p); return file_time_type::min(); } return detail::convert_timespec(ts); } void __last_write_time(const path& p, file_time_type new_time, std::error_code *ec) { using namespace std::chrono; std::error_code m_ec; // We can use the presence of UTIME_OMIT to detect platforms that do not // provide utimensat. #if !defined(UTIME_OMIT) // This implementation has a race condition between determining the // last access time and attempting to set it to the same value using // ::utimes struct ::stat st; file_status fst = detail::posix_stat(p, st, &m_ec); if (m_ec && !status_known(fst)) { set_or_throw(m_ec, ec, "last_write_time", p); return; } auto atime = detail::extract_atime(st); struct ::timeval tbuf[2]; tbuf[0].tv_sec = atime.tv_sec; tbuf[0].tv_usec = duration_cast(nanoseconds(atime.tv_nsec)).count(); const bool overflowed = !detail::set_times_checked( &tbuf[1].tv_sec, &tbuf[1].tv_usec, new_time); if (overflowed) { set_or_throw(make_error_code(errc::invalid_argument), ec, "last_write_time", p); return; } if (::utimes(p.c_str(), tbuf) == -1) { m_ec = detail::capture_errno(); } #else struct ::timespec tbuf[2]; tbuf[0].tv_sec = 0; tbuf[0].tv_nsec = UTIME_OMIT; const bool overflowed = !detail::set_times_checked( &tbuf[1].tv_sec, &tbuf[1].tv_nsec, new_time); if (overflowed) { set_or_throw(make_error_code(errc::invalid_argument), ec, "last_write_time", p); return; } if (::utimensat(AT_FDCWD, p.c_str(), tbuf, 0) == -1) { m_ec = detail::capture_errno(); } #endif if (m_ec) set_or_throw(m_ec, ec, "last_write_time", p); else if (ec) ec->clear(); } void __permissions(const path& p, perms prms, std::error_code *ec) { const bool resolve_symlinks = !bool(perms::symlink_nofollow & prms); const bool add_perms = bool(perms::add_perms & prms); const bool remove_perms = bool(perms::remove_perms & prms); _LIBCPP_ASSERT(!(add_perms && remove_perms), "Both add_perms and remove_perms are set"); bool set_sym_perms = false; prms &= perms::mask; if (!resolve_symlinks || (add_perms || remove_perms)) { std::error_code m_ec; file_status st = resolve_symlinks ? detail::posix_stat(p, &m_ec) : detail::posix_lstat(p, &m_ec); set_sym_perms = is_symlink(st); if (m_ec) return set_or_throw(m_ec, ec, "permissions", p); _LIBCPP_ASSERT(st.permissions() != perms::unknown, "Permissions unexpectedly unknown"); if (add_perms) prms |= st.permissions(); else if (remove_perms) prms = st.permissions() & ~prms; } const auto real_perms = detail::posix_convert_perms(prms); # if defined(AT_SYMLINK_NOFOLLOW) && defined(AT_FDCWD) const int flags = set_sym_perms ? AT_SYMLINK_NOFOLLOW : 0; if (::fchmodat(AT_FDCWD, p.c_str(), real_perms, flags) == -1) { return set_or_throw(ec, "permissions", p); } # else if (set_sym_perms) return set_or_throw(make_error_code(errc::operation_not_supported), ec, "permissions", p); if (::chmod(p.c_str(), real_perms) == -1) { return set_or_throw(ec, "permissions", p); } # endif if (ec) ec->clear(); } path __read_symlink(const path& p, std::error_code *ec) { char buff[PATH_MAX + 1]; std::error_code m_ec; ::ssize_t ret; if ((ret = ::readlink(p.c_str(), buff, PATH_MAX)) == -1) { set_or_throw(ec, "read_symlink", p); return {}; } _LIBCPP_ASSERT(ret <= PATH_MAX, "TODO"); _LIBCPP_ASSERT(ret > 0, "TODO"); if (ec) ec->clear(); buff[ret] = 0; return {buff}; } bool __remove(const path& p, std::error_code *ec) { if (ec) ec->clear(); if (::remove(p.c_str()) == -1) { set_or_throw(ec, "remove", p); return false; } return true; } namespace { std::uintmax_t remove_all_impl(path const & p, std::error_code& ec) { const auto npos = static_cast(-1); const file_status st = __symlink_status(p, &ec); if (ec) return npos; std::uintmax_t count = 1; if (is_directory(st)) { for (directory_iterator it(p, ec); !ec && it != directory_iterator(); it.increment(ec)) { auto other_count = remove_all_impl(it->path(), ec); if (ec) return npos; count += other_count; } if (ec) return npos; } if (!__remove(p, &ec)) return npos; return count; } } // end namespace std::uintmax_t __remove_all(const path& p, std::error_code *ec) { std::error_code mec; auto count = remove_all_impl(p, mec); if (mec) { set_or_throw(mec, ec, "remove_all", p); return static_cast(-1); } if (ec) ec->clear(); return count; } void __rename(const path& from, const path& to, std::error_code *ec) { if (::rename(from.c_str(), to.c_str()) == -1) set_or_throw(ec, "rename", from, to); else if (ec) ec->clear(); } void __resize_file(const path& p, std::uintmax_t size, std::error_code *ec) { if (::truncate(p.c_str(), static_cast(size)) == -1) set_or_throw(ec, "resize_file", p); else if (ec) ec->clear(); } space_info __space(const path& p, std::error_code *ec) { space_info si; struct statvfs m_svfs = {}; if (::statvfs(p.c_str(), &m_svfs) == -1) { set_or_throw(ec, "space", p); si.capacity = si.free = si.available = static_cast(-1); return si; } if (ec) ec->clear(); // Multiply with overflow checking. auto do_mult = [&](std::uintmax_t& out, std::uintmax_t other) { out = other * m_svfs.f_frsize; if (other == 0 || out / other != m_svfs.f_frsize) out = static_cast(-1); }; do_mult(si.capacity, m_svfs.f_blocks); do_mult(si.free, m_svfs.f_bfree); do_mult(si.available, m_svfs.f_bavail); return si; } file_status __status(const path& p, std::error_code *ec) { return detail::posix_stat(p, ec); } file_status __symlink_status(const path& p, std::error_code *ec) { return detail::posix_lstat(p, ec); } path __system_complete(const path& p, std::error_code *ec) { if (ec) ec->clear(); return absolute(p, current_path()); } path __temp_directory_path(std::error_code* ec) { const char* env_paths[] = {"TMPDIR", "TMP", "TEMP", "TEMPDIR"}; const char* ret = nullptr; for (auto& ep : env_paths) if ((ret = std::getenv(ep))) break; if (ret == nullptr) ret = "/tmp"; path p(ret); std::error_code m_ec; if (!exists(p, m_ec) || !is_directory(p, m_ec)) { if (!m_ec || m_ec == make_error_code(errc::no_such_file_or_directory)) m_ec = make_error_code(errc::not_a_directory); set_or_throw(m_ec, ec, "temp_directory_path"); return {}; } if (ec) ec->clear(); return p; } // An absolute path is composed according to the table in [fs.op.absolute]. path absolute(const path& p, const path& base) { auto root_name = p.root_name(); auto root_dir = p.root_directory(); if (!root_name.empty() && !root_dir.empty()) return p; auto abs_base = base.is_absolute() ? base : absolute(base); /* !has_root_name && !has_root_dir */ if (root_name.empty() && root_dir.empty()) { return abs_base / p; } else if (!root_name.empty()) /* has_root_name && !has_root_dir */ { return root_name / abs_base.root_directory() / abs_base.relative_path() / p.relative_path(); } else /* !has_root_name && has_root_dir */ { if (abs_base.has_root_name()) return abs_base.root_name() / p; // else p is absolute, return outside of block } return p; } _LIBCPP_END_NAMESPACE_EXPERIMENTAL_FILESYSTEM