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construct/ircd/fs.cc

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C++

// Matrix Construct
//
// Copyright (C) Matrix Construct Developers, Authors & Contributors
// Copyright (C) 2016-2018 Jason Volk <jason@zemos.net>
//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
// copyright notice and this permission notice is present in all copies. The
// full license for this software is available in the LICENSE file.
#include <RB_INC_FCNTL_H
#include <RB_INC_SYS_STAT_H
#include <RB_INC_SYS_STATFS_H
#include <RB_INC_SYS_STATVFS_H
#include <RB_INC_SYS_RESOURCE_H
#include <boost/filesystem.hpp>
#ifdef IRCD_USE_AIO
#include "fs_aio.h"
#endif
#ifdef IRCD_USE_IOU
#include "fs_iou.h"
#endif
// TODO: prevents use until io_uring support implemented
#undef IRCD_USE_IOU
namespace ircd::fs
{
extern conf::item<ulong> rlimit_nofile;
static void update_rlimit_nofile();
static void init_dump_info();
}
decltype(ircd::fs::log)
ircd::fs::log
{
"fs"
};
decltype(ircd::fs::rlimit_nofile)
ircd::fs::rlimit_nofile
{
{
{ "name", "ircd.fs.rlimit.nofile" },
{ "default", 65535L },
{ "persist", false },
},
update_rlimit_nofile
};
//
// init::init
//
ircd::fs::init::init()
{
init_dump_info();
}
ircd::fs::init::~init()
noexcept
{
}
void
ircd::fs::init_dump_info()
{
const bool support_async
{
false || iou::system || aio::system
};
if(!support_async)
log::warning
{
log, "Support for asynchronous filesystem IO has not been"
" established. Filesystem IO is degraded to synchronous system calls."
};
}
#if defined(HAVE_SYS_RESOURCE_H) && defined(RLIMIT_NOFILE)
void
ircd::fs::update_rlimit_nofile()
try
{
rlimit rlim[2];
syscall(getrlimit, RLIMIT_NOFILE, &rlim[0]);
rlim[1] = rlim[0];
rlim[1].rlim_cur = std::max(rlim[1].rlim_cur, ulong(fs::rlimit_nofile));
rlim[1].rlim_cur = std::min(rlim[1].rlim_cur, rlim[1].rlim_max);
if(rlim[0].rlim_cur == rlim[1].rlim_cur)
return;
syscall(setrlimit, RLIMIT_NOFILE, &rlim[1]);
log::info
{
log, "Raised resource limit for number of open files from %ld to %ld",
rlim[0].rlim_cur,
rlim[1].rlim_cur,
};
}
catch(const std::system_error &e)
{
log::warning
{
log, "Failed to raise resource limit for number of open files :%s",
e.what()
};
}
#else
void
ircd::fs::init_rlimit_nofile()
{
log::dwarning
{
log, "Cannot modify resource limit for number of open files."
};
}
#endif
///////////////////////////////////////////////////////////////////////////////
//
// fs/support.h
//
decltype(ircd::fs::support::pwritev2)
ircd::fs::support::pwritev2
{
#if defined(HAVE_PWRITEV2)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 6)
#else
false
#endif
};
decltype(ircd::fs::support::preadv2)
ircd::fs::support::preadv2
{
#if defined(HAVE_PREADV2)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 6)
#else
false
#endif
};
decltype(ircd::fs::support::sync)
ircd::fs::support::sync
{
#if defined(HAVE_PWRITEV2) && defined(RWF_SYNC)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 7)
#else
false
#endif
};
decltype(ircd::fs::support::dsync)
ircd::fs::support::dsync
{
#if defined(HAVE_PWRITEV2) && defined(RWF_DSYNC)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 7)
#else
false
#endif
};
decltype(ircd::fs::support::hipri)
ircd::fs::support::hipri
{
#if defined(HAVE_PWRITEV2) && defined(RWF_HIPRI)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 6)
#else
false
#endif
};
decltype(ircd::fs::support::nowait)
ircd::fs::support::nowait
{
#if defined(HAVE_PWRITEV2) && defined(RWF_NOWAIT)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 14)
#else
false
#endif
};
decltype(ircd::fs::support::append)
ircd::fs::support::append
{
#if defined(HAVE_PWRITEV2) && defined(RWF_APPEND)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 16)
#else
false
#endif
};
decltype(ircd::fs::support::rwh_write_life)
ircd::fs::support::rwh_write_life
{
#if defined(HAVE_FCNTL_H) && defined(F_SET_FILE_RW_HINT)
info::kernel_version[0] > 4 ||
(info::kernel_version[0] >= 4 && info::kernel_version[1] >= 13)
#else
false
#endif
};
decltype(ircd::fs::support::rwf_write_life)
ircd::fs::support::rwf_write_life
{
#if defined(RWF_WRITE_LIFE_SHIFT)
false //TODO: XXX
#else
false
#endif
};
decltype(ircd::fs::support::aio)
ircd::fs::support::aio
{
#ifdef IRCD_USE_AIO
true
#else
false
#endif
};
void
ircd::fs::support::dump_info()
{
#if defined(IRCD_USE_AIO) || defined(IRCD_USE_IOU)
const bool support_async {true};
#else
const bool support_async {false};
#endif
char support[128] {0};
const auto _append{[&support]
(const string_view &name, const bool &avail, const int &enable)
{
strlcat(support, fmt::bsprintf<64>
{
"%s:%c%s ",
name,
avail == true? 'y': 'n',
enable == true? "y": enable == false? "n": "",
});
}};
_append("async", support_async, -1);
_append("preadv2", preadv2, -1);
_append("pwritev2", pwritev2, -1);
_append("SYNC", sync, -1);
_append("DSYNC", dsync, -1);
_append("HIPRI", hipri, -1);
_append("NOWAIT", nowait, -1);
_append("APPEND", append, -1);
_append("RWH", rwh_write_life, -1);
_append("RWF", rwf_write_life, -1);
log::info
{
log, "VFS %s",
support
};
#ifdef RB_DEBUG
const unique_mutable_buffer buf
{
PATH_MAX_LEN + 1
};
log::debug
{
log, "Current working directory: `%s'", cwd(buf)
};
#endif
}
bool
ircd::fs::support::fallocate(const string_view &path,
const write_opts &wopts)
try
{
const fd::opts opts
{
std::ios::out
};
fs::fd fd
{
path, opts
};
fs::allocate(fd, info::page_size, wopts);
return true;
}
catch(const std::system_error &e)
{
const auto &ec(e.code());
if(system_category(ec)) switch(ec.value())
{
case int(std::errc::invalid_argument):
case int(std::errc::operation_not_supported):
return false;
default:
break;
}
throw;
}
bool
ircd::fs::support::direct_io(const string_view &path)
try
{
fd::opts opts{std::ios::out};
opts.direct = true;
fd{path, opts};
return true;
}
catch(const std::system_error &e)
{
const auto &ec(e.code());
if(system_category(ec)) switch(ec.value())
{
case int(std::errc::invalid_argument):
return false;
default:
break;
}
throw;
}
#if defined(HAVE_SYS_RESOURCE_H) && defined(RLIMIT_FSIZE)
size_t
ircd::fs::support::rlimit_fsize()
{
rlimit rlim;
syscall(getrlimit, RLIMIT_FSIZE, &rlim);
return rlim.rlim_cur;
}
#else
size_t
ircd::fs::support::rlimit_fize()
{
return -1;
}
#endif
#if defined(HAVE_SYS_RESOURCE_H) && defined(RLIMIT_NOFILE)
size_t
ircd::fs::support::rlimit_nofile()
{
rlimit rlim;
syscall(getrlimit, RLIMIT_NOFILE, &rlim);
return rlim.rlim_cur;
}
#else
size_t
ircd::fs::support::rlimit_nofile()
{
return -1;
}
#endif
///////////////////////////////////////////////////////////////////////////////
//
// fs.h / misc
//
bool
ircd::fs::mkdir(const string_view &path)
try
{
return filesystem::create_directories(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::remove(const string_view &path)
try
{
const prof::syscall_usage_warning message
{
"fs::remove(%s)", path
};
return filesystem::remove(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::remove(std::nothrow_t,
const string_view &path)
{
const prof::syscall_usage_warning message
{
"fs::remove(%s)", path
};
boost::system::error_code ec;
return filesystem::remove(_path(path), ec);
}
bool
ircd::fs::rename(const string_view &old,
const string_view &new_)
try
{
const prof::syscall_usage_warning message
{
"fs::rename(%s, %s)", old, new_
};
filesystem::rename(_path(old), _path(new_));
return true;
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::rename(std::nothrow_t,
const string_view &old,
const string_view &new_)
{
const prof::syscall_usage_warning message
{
"fs::rename(%s, %s)", old, new_
};
boost::system::error_code ec;
filesystem::rename(_path(old), _path(new_), ec);
return !ec;
}
std::vector<std::string>
ircd::fs::ls_r(const string_view &path)
try
{
const filesystem::recursive_directory_iterator end;
filesystem::recursive_directory_iterator it
{
_path(path)
};
std::vector<std::string> ret;
std::for_each(it, end, [&ret]
(const auto &ent)
{
ret.emplace_back(ent.path().string());
});
return ret;
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
std::vector<std::string>
ircd::fs::ls(const string_view &path)
try
{
static const filesystem::directory_iterator end;
filesystem::directory_iterator it
{
_path(path)
};
std::vector<std::string> ret;
std::for_each(it, end, [&ret]
(const auto &ent)
{
ret.emplace_back(ent.path().string());
});
return ret;
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
size_t
ircd::fs::size(const string_view &path)
try
{
return filesystem::file_size(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::is_exec(const string_view &path)
try
{
return filesystem::status(_path(path)).permissions() & filesystem::owner_exe;
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::is_reg(const string_view &path)
try
{
return filesystem::is_regular_file(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::is_dir(const string_view &path)
try
{
return filesystem::is_directory(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
bool
ircd::fs::exists(const string_view &path)
try
{
return filesystem::exists(_path(path));
}
catch(const filesystem::filesystem_error &e)
{
throw error{e};
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/stdin.h
//
ircd::string_view
ircd::fs::stdin::readline(const mutable_buffer &buf)
try
{
boost::asio::posix::stream_descriptor fd
{
ios::get(), dup(STDIN_FILENO)
};
boost::asio::streambuf sb
{
size(buf)
};
const auto interruption{[&fd]
(ctx::ctx *const &interruptor)
{
fd.cancel();
}};
size_t len; continuation
{
continuation::asio_predicate, interruption, [&len, &fd, &sb]
(auto &yield)
{
len = boost::asio::async_read_until(fd, sb, '\n', yield);
}
};
std::istream is{&sb};
is.get(data(buf), size(buf), '\n');
return string_view
{
data(buf), size_t(is.gcount())
};
}
catch(boost::system::system_error &e)
{
throw_system_error(e.code());
__builtin_unreachable();
}
//
// tty
//
ircd::fs::stdin::tty::tty()
:fd{[]
{
thread_local char buf[256];
syscall(::ttyname_r, STDIN_FILENO, buf, sizeof(buf));
return fd
{
string_view{buf}, std::ios_base::out
};
}()}
{
}
size_t
ircd::fs::stdin::tty::write(const string_view &buf)
{
return syscall(::write, int(*this), buf.data(), buf.size());
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/select.h
//
size_t
ircd::fs::select(const vector_view<const fd> &fd_)
{
using asio::posix::stream_descriptor;
static ios::descriptor desc
{
"ircd::fs::select"
};
const size_t num(size(fd_));
std::optional<stream_descriptor> _fd[num];
const unwind release{[&_fd]
{
for(auto &fd : _fd)
if(fd)
fd->release();
}};
size_t ret(-1);
ctx::latch latch(num);
const auto callback{[&num, &_fd, &latch, &ret]
(const boost::system::error_code &ec, const auto &fd)
{
// The first successful callback is associated with an input fd
// and its array indice becomes the return value.
if(!ec && ret == size_t(-1))
{
const auto it
{
std::find_if(_fd, _fd + num, [&fd]
(const auto &_fd)
{
return _fd && std::addressof(*_fd) == std::addressof(*fd);
})
};
ret = std::distance(_fd, it);
assert(ret < num);
}
latch.count_down();
}};
for(size_t i(0); i < num; ++i)
{
// Allow a closed descriptor in the vector to be no-op.
if(!fd_[i])
{
latch.count_down();
continue;
}
_fd[i] =
{
ios::get(), int(fd_[i])
};
auto handle
{
std::bind(callback, ph::_1, std::cref(_fd[i]))
};
_fd[i]->async_wait(stream_descriptor::wait_read, ios::handle(desc, std::move(handle)));
}
std::exception_ptr eptr; try
{
latch.wait();
assert(ret < num);
return ret;
}
catch(...)
{
eptr = std::current_exception();
const ctx::exception_handler eh;
const ctx::uninterruptible::nothrow ui;
for(auto &fd : _fd)
fd->cancel();
latch.wait();
assert(eptr);
std::rethrow_exception(eptr);
}
return ret;
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/sync.h
//
ircd::fs::sync_opts
const ircd::fs::sync_opts_default;
void
ircd::fs::sync(const fd &fd,
const off_t &offset,
const size_t &length,
const sync_opts &opts)
{
return sync(fd, opts);
}
void
ircd::fs::sync(const fd &fd,
const sync_opts &opts)
{
assert(opts.op == op::SYNC);
const prof::syscall_usage_warning message
{
"fs::sync(fd:%d)", int(fd)
};
#ifdef __linux__
syscall(::syncfs, fd);
#else
syscall(::sync);
#endif
}
void
ircd::fs::flush(const fd &fd,
const off_t &offset,
const size_t &length,
const sync_opts &opts)
{
return flush(fd, opts);
}
void
ircd::fs::flush(const fd &fd,
const sync_opts &opts)
{
assert(opts.op == op::SYNC);
#ifdef IRCD_USE_IOU
if(iou::system && opts.aio)
return iou::fsync(fd, opts);
#endif
#ifdef IRCD_USE_AIO
if(aio::system && opts.aio)
{
if(support::aio_fdsync && !opts.metadata)
aio::fsync(fd, opts);
if(support::aio_fsync && opts.metadata)
aio::fsync(fd, opts);
}
#endif
const prof::syscall_usage_warning message
{
"fs::flush(fd:%d, {metadata:%b aio:%b:%b})",
int(fd),
opts.metadata,
opts.aio,
opts.metadata? support::aio_fsync : support::aio_fdsync
};
if(!opts.metadata)
return void(syscall(::fdatasync, fd));
return void(syscall(::fsync, fd));
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/read.h
//
ircd::fs::read_opts
const ircd::fs::read_opts_default
{};
size_t
ircd::fs::prefetch(const fd &fd,
const size_t &count,
const read_opts &opts)
{
#if defined(POSIX_FADV_WILLNEED)
return advise(fd, POSIX_FADV_WILLNEED, count, opts);
#else
return 0UL;
#endif
}
bool
ircd::fs::incore(const fd &fd,
const size_t &count,
const read_opts &opts)
{
fs::map::opts map_opts;
map_opts.offset = buffer::align(opts.offset, info::page_size);
map_opts.blocking = false;
const size_t &map_size
{
count?: size(fd)
};
const size_t &map_pages
{
(map_size + info::page_size - 1) / info::page_size
};
assert(map_opts.offset % 4096 == 0);
const fs::map map
{
fd, map_opts, map_size
};
const size_t res
{
allocator::incore(map)
};
return res == map_size;
}
std::string
ircd::fs::read(const fd &fd,
const read_opts &opts)
{
return string(size(fd), [&fd, &opts]
(const mutable_buffer &buf)
{
return read(fd, buf, opts);
});
}
ircd::const_buffer
ircd::fs::read(const fd &fd,
const mutable_buffer &buf,
const read_opts &opts)
{
const mutable_buffers bufs
{
&buf, 1
};
return mutable_buffer
{
data(buf), read(fd, bufs, opts)
};
}
size_t
ircd::fs::read(const vector_view<read_op> &op)
{
// Use IOV_MAX as a sanity value for number of operations here
if(unlikely(op.size() > info::iov_max))
throw error
{
make_error_code(std::errc::invalid_argument),
"Read operation count:%zu exceeds max:%zu",
op.size(),
info::iov_max,
};
bool aio {true}, all {false};
for(size_t i(0); i < op.size(); ++i)
{
assert(op[i].opts);
assert(op[i].opts->aio);
// If any op isn't tolerant of less bytes actually read than they
// requested, they require us to perform the unix read loop, and
// that ruins things for everybody!
assert(!op[i].opts->all);
//all |= op[i].opts->all;
// If any op doesn't want AIO we have to fallback on sequential
// blocking reads for all ops.
assert(op[i].opts->aio);
//aio &= op[i].opts->aio;
// EINVAL for exceeding this system's IOV_MAX
if(unlikely(op[i].bufs.size() > info::iov_max))
throw error
{
make_error_code(std::errc::invalid_argument),
"op[%zu] :buffer count of %zu exceeds IOV_MAX of %zu",
i,
op[i].bufs.size(),
info::iov_max,
};
}
#ifdef IRCD_USE_AIO
if(likely(aio::system && aio && !all))
return aio::read(op);
#endif
// Fallback to sequential read operations
size_t ret(0);
for(size_t i(0); i < op.size(); ++i) try
{
assert(op[i].fd);
assert(op[i].opts);
op[i].ret = read(*op[i].fd, op[i].bufs, *op[i].opts);
ret += op[i].ret;
}
catch(const std::system_error &)
{
op[i].eptr = std::current_exception();
op[i].ret = 0;
}
return ret;
}
namespace ircd::fs
{
static int flags(const read_opts &opts);
static size_t _read_preadv2(const fd &, const const_iovec_view &, const read_opts &);
static size_t _read_preadv(const fd &, const const_iovec_view &, const read_opts &);
static size_t read(const fd &, const const_iovec_view &, const read_opts &);
}
/// Read from file descriptor fd into buffers. The number of bytes read into
/// the buffers is returned. By default (via read_opts.all) this call will
/// loop internally until the buffers are full or EOF. To allow for a partial
/// read(), disable read_opts.all. Note that to maintain alignments (i.e when
/// direct-io or for special files read_opts.all must be false). By default
/// (via read_opts.interruptible) this call can throw if the syscall was
/// interrupted before reading any bytes.
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wstack-usage="
size_t
__attribute__((stack_protect))
ircd::fs::read(const fd &fd,
const mutable_buffers &bufs,
const read_opts &opts_)
{
if(unlikely(bufs.size() > info::iov_max))
throw error
{
make_error_code(std::errc::invalid_argument),
"Buffer count of %zu exceeds IOV_MAX of %zu",
bufs.size(),
info::iov_max
};
size_t ret(0);
read_opts opts(opts_);
assert(bufs.size() <= info::iov_max);
struct ::iovec iovbuf[bufs.size()]; do
{
assert(opts.offset >= opts_.offset);
const size_t off(opts.offset - opts_.offset);
assert(off <= buffers::size(bufs));
assert(ret <= buffers::size(bufs));
const auto iov
{
make_iov({iovbuf, bufs.size()}, bufs, ret)
};
const size_t last
{
read(fd, iov, opts)
};
if(!opts_.blocking && !last)
break;
ret += last;
if(!opts_.all)
break;
if(off >= ret)
break;
opts.offset = opts_.offset + ret;
}
while(ret < buffers::size(bufs));
assert(opts.offset >= opts_.offset);
assert(ret <= buffers::size(bufs));
return ret;
}
#pragma GCC diagnostic pop
/// Lowest-level'ish read() call. This call only conducts a single operation
/// (no looping) and can return a partial read(). It does have branches
/// for various read_opts. The arguments involve `struct ::iovec` which
/// we do not expose to the ircd.h API; thus this function is internal to
/// ircd::fs. There is no reason to use this function in lieu of the public
/// fs::read() suite.
size_t
ircd::fs::read(const fd &fd,
const const_iovec_view &iov,
const read_opts &opts)
{
assert(opts.op == op::READ);
#ifdef IRCD_USE_IOU
if(likely(iou::system && opts.aio))
return iou::read(fd, iov, opts);
#endif
#ifdef IRCD_USE_AIO
if(likely(aio::system && opts.aio))
return aio::read(fd, iov, opts);
#endif
#ifdef HAVE_PREADV2
return support::preadv2?
_read_preadv2(fd, iov, opts):
_read_preadv(fd, iov, opts);
#else
return _read_preadv(fd, iov, opts);
#endif
}
size_t
ircd::fs::_read_preadv(const fd &fd,
const const_iovec_view &iov,
const read_opts &opts)
{
ssize_t ret; do
{
ret = ::preadv(int(fd), iov.data(), iov.size(), opts.offset);
}
while(!opts.interruptible && unlikely(ret == -1 && errno == EINTR));
static_assert(EAGAIN == EWOULDBLOCK);
if(unlikely(!opts.blocking && ret == -1 && errno == EAGAIN))
return 0UL;
if(unlikely(ret == -1))
throw std::system_error
{
errno, std::system_category()
};
return ret;
}
#ifdef HAVE_PREADV2
size_t
ircd::fs::_read_preadv2(const fd &fd,
const const_iovec_view &iov,
const read_opts &opts)
{
const auto &flags_
{
flags(opts)
};
ssize_t ret; do
{
ret = ::preadv2(int(fd), iov.data(), iov.size(), opts.offset, flags_);
}
while(!opts.interruptible && unlikely(ret == -1 && errno == EINTR));
static_assert(EAGAIN == EWOULDBLOCK);
if(!opts.blocking && ret == -1 && errno == EAGAIN)
return 0UL;
if(unlikely(ret == -1))
throw std::system_error
{
errno, std::system_category()
};
return ret;
}
#endif HAVE_PREADV2
int
ircd::fs::flags(const read_opts &opts)
{
int ret{0};
#if defined(RWF_HIPRI)
if(support::hipri && reqprio(opts.priority) == reqprio(opts::highest_priority))
ret |= RWF_HIPRI;
#endif
#if defined(RWF_NOWAIT)
if(support::nowait && !opts.blocking)
ret |= RWF_NOWAIT;
#endif
return ret;
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/write.h
//
ircd::fs::write_opts
const ircd::fs::write_opts_default
{};
void
ircd::fs::allocate(const fd &fd,
const size_t &size,
const write_opts &opts)
{
assert(opts.op == op::WRITE);
int mode{0};
#ifdef FALLOC_FL_KEEP_SIZE
mode |= opts.keep_size? FALLOC_FL_KEEP_SIZE : 0;
#else
if(opts.keep_size)
throw_system_error(std::errc::invalid_argument);
#endif
#ifdef FALLOC_FL_PUNCH_HOLE
mode |= opts.punch_hole? FALLOC_FL_PUNCH_HOLE : 0;
#else
if(opts.punch_hole)
throw_system_error(std::errc::invalid_argument);
#endif
syscall(::fallocate, fd, mode, opts.offset, size);
}
void
ircd::fs::truncate(const string_view &path,
const size_t &size,
const write_opts &opts)
{
const fd fd
{
path, std::ios::out | std::ios::trunc
};
return truncate(fd, size, opts);
}
void
ircd::fs::truncate(const fd &fd,
const size_t &size,
const write_opts &opts)
{
assert(opts.op == op::WRITE);
syscall(::ftruncate, fd, size);
}
ircd::const_buffer
ircd::fs::overwrite(const string_view &path,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), overwrite(path, bufs, opts)
};
}
ircd::const_buffer
ircd::fs::overwrite(const fd &fd,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), overwrite(fd, bufs, opts)
};
}
size_t
ircd::fs::overwrite(const string_view &path,
const const_buffers &bufs,
const write_opts &opts)
{
const fd fd
{
path, std::ios::out | std::ios::trunc
};
return overwrite(fd, bufs, opts);
}
size_t
ircd::fs::overwrite(const fd &fd,
const const_buffers &bufs,
const write_opts &opts)
{
return write(fd, bufs, opts);
}
//
// append
//
ircd::const_buffer
ircd::fs::append(const string_view &path,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), append(path, bufs, opts)
};
}
ircd::const_buffer
ircd::fs::append(const fd &fd,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), append(fd, bufs, opts)
};
}
size_t
ircd::fs::append(const string_view &path,
const const_buffers &bufs,
const write_opts &opts)
{
const fd fd
{
path, std::ios::out | std::ios::app
};
return append(fd, bufs, opts);
}
size_t
ircd::fs::append(const fd &fd,
const const_buffers &bufs,
const write_opts &opts_)
{
auto opts(opts_);
if(support::pwritev2 && support::append)
opts.offset = -1;
else if(!opts.offset || opts.offset == -1)
opts.offset = syscall(::lseek, fd, 0, SEEK_END);
return write(fd, bufs, opts);
}
//
// write
//
ircd::const_buffer
ircd::fs::write(const string_view &path,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), write(path, bufs, opts)
};
}
ircd::const_buffer
ircd::fs::write(const fd &fd,
const const_buffer &buf,
const write_opts &opts)
{
const const_buffers bufs
{
&buf, 1
};
return const_buffer
{
data(buf), write(fd, bufs, opts)
};
}
size_t
ircd::fs::write(const string_view &path,
const const_buffers &bufs,
const write_opts &opts)
{
const fd fd
{
path, std::ios::out
};
return write(fd, bufs, opts);
}
namespace ircd::fs
{
static int flags(const write_opts &opts);
static size_t _write_pwritev2(const fd &, const const_iovec_view &, const write_opts &);
static size_t _write_pwritev(const fd &, const const_iovec_view &, const write_opts &);
static size_t write(const fd &, const const_iovec_view &, const write_opts &);
}
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wstack-usage="
size_t
__attribute__((stack_protect))
ircd::fs::write(const fd &fd,
const const_buffers &bufs,
const write_opts &opts_)
{
if(unlikely(bufs.size() > info::iov_max))
throw error
{
make_error_code(std::errc::invalid_argument),
"Buffer count of %zu exceeds IOV_MAX of %zu",
bufs.size(),
info::iov_max
};
size_t off(0);
write_opts opts(opts_);
assert(bufs.size() <= info::iov_max);
struct ::iovec iovbuf[bufs.size()]; do
{
const auto iov
{
make_iov({iovbuf, bufs.size()}, bufs, off)
};
const size_t last
{
write(fd, iov, opts)
};
opts.offset += last;
assert(opts.offset >= opts_.offset);
off = opts.offset - opts_.offset;
if(!opts.blocking && !last)
break;
}
while(opts.all && opts_.offset >= 0 && off < buffers::size(bufs));
assert(opts.offset >= opts_.offset);
assert(ssize_t(off) == opts.offset - opts_.offset);
assert(!opts.all || !opts.blocking || off == buffers::size(bufs));
return off;
}
#pragma GCC diagnostic pop
/// Lowest-level'ish write() call. This call only conducts a single operation
/// (no looping) and can return early with a partial write(). It does have
/// branches for various write_opts. The arguments involve `struct ::iovec`
/// which we do not expose to the ircd.h API; thus this function is internal to
/// ircd::fs. There is no reason to use this function in lieu of the public
/// fs::read() suite.
size_t
ircd::fs::write(const fd &fd,
const const_iovec_view &iov,
const write_opts &opts)
{
assert(opts.op == op::WRITE);
#ifdef IRCD_USE_IOU
if(likely(iou::system && opts.aio))
return iou::write(fd, iov, opts);
#endif
#ifdef IRCD_USE_AIO
if(likely(aio::system && opts.aio))
return aio::write(fd, iov, opts);
#endif
#ifdef HAVE_PWRITEV2
return support::pwritev2?
_write_pwritev2(fd, iov, opts):
_write_pwritev(fd, iov, opts);
#else
return _write_pwritev(fd, iov, opts);
#endif
}
size_t
ircd::fs::_write_pwritev(const fd &fd,
const const_iovec_view &iov,
const write_opts &opts)
{
ssize_t ret; do
{
ret = ::pwritev(int(fd), iov.data(), iov.size(), opts.offset);
}
while(!opts.interruptible && unlikely(ret == -1 && errno == EINTR));
static_assert(EAGAIN == EWOULDBLOCK);
if(unlikely(!opts.blocking && ret == -1 && errno == EAGAIN))
return 0UL;
if(unlikely(ret == -1))
throw std::system_error
{
errno, std::system_category()
};
return ret;
}
#ifdef HAVE_PWRITEV2
size_t
ircd::fs::_write_pwritev2(const fd &fd,
const const_iovec_view &iov,
const write_opts &opts)
{
// Manpages sez that when appending with RWF_APPEND, the offset has no
// effect on the write; but if the value of the offset is -1 then the
// fd's offset is updated, otherwise it is not.
const off_t &offset
{
opts.offset == -1 && !opts.update_offset? 0 : opts.offset
};
ssize_t ret; do
{
ret = ::pwritev2(int(fd), iov.data(), iov.size(), opts.offset, flags(opts));
}
while(!opts.interruptible && unlikely(ret == -1 && errno == EINTR));
static_assert(EAGAIN == EWOULDBLOCK);
if(!opts.blocking && ret == -1 && errno == EAGAIN)
return 0UL;
if(unlikely(ret == -1))
throw std::system_error
{
errno, std::system_category()
};
return ret;
}
#endif HAVE_PWRITEV2
int
ircd::fs::flags(const write_opts &opts)
{
int ret{0};
#if defined(RWF_APPEND)
assert(opts.offset >= 0 || support::append);
if(support::append && opts.offset == -1)
ret |= RWF_APPEND;
#endif
#if defined(RWF_HIPRI)
if(support::hipri && reqprio(opts.priority) == reqprio(opts::highest_priority))
ret |= RWF_HIPRI;
#endif
#if defined(RWF_NOWAIT)
if(support::nowait && !opts.blocking)
ret |= RWF_NOWAIT;
#endif
#if defined(RWF_DSYNC)
if(support::dsync && opts.sync && !opts.metadata)
ret |= RWF_DSYNC;
#endif
#if defined(RWF_SYNC)
if(support::sync && opts.sync && opts.metadata)
ret |= RWF_SYNC;
#endif
#ifdef RWF_WRITE_LIFE_SHIFT
if(support::rwf_write_life && opts.write_life)
ret |= (opts.write_life << (RWF_WRITE_LIFE_SHIFT));
#endif
return ret;
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/wait.h
//
namespace ircd::fs
{
static constexpr asio::posix::stream_descriptor::wait_type translate(const ready &) noexcept
__attribute__((const));
}
decltype(ircd::fs::wait_opts_default)
ircd::fs::wait_opts_default;
void
ircd::fs::wait(const fd &fd,
const wait_opts &opts)
{
assert(opts.op == op::WAIT);
const auto &wait_type
{
translate(opts.ready)
};
boost::asio::posix::stream_descriptor sd
{
ios::get(), int(fd)
};
const unwind release{[&sd]
{
sd.release();
}};
const auto interruption{[&sd]
(ctx::ctx *const &interruptor)
{
sd.cancel();
}};
boost::system::error_code ec; continuation
{
continuation::asio_predicate, interruption, [&wait_type, &sd, &ec]
(auto &yield)
{
sd.async_wait(wait_type, yield[ec]);
}
};
if(unlikely(ec))
throw_system_error(ec);
}
constexpr
boost::asio::posix::stream_descriptor::wait_type
ircd::fs::translate(const ready &ready)
noexcept
{
using wait_type = boost::asio::posix::stream_descriptor::wait_type;
switch(ready)
{
case ready::ANY:
return wait_type::wait_read | wait_type::wait_write | wait_type::wait_error;
case ready::READ:
return wait_type::wait_read;
case ready::WRITE:
return wait_type::wait_write;
case ready::ERROR:
default:
return wait_type::wait_error;
}
}
ircd::string_view
ircd::fs::reflect(const ready &ready)
{
switch(ready)
{
case ready::ANY: return "ANY";
case ready::READ: return "READ";
case ready::WRITE: return "WRITE";
case ready::ERROR: return "ERROR";
}
return "?????";
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/aio.h
//
decltype(ircd::fs::aio::MAX_EVENTS)
ircd::fs::aio::MAX_EVENTS
{
info::aio_max
};
decltype(ircd::fs::aio::MAX_REQPRIO)
ircd::fs::aio::MAX_REQPRIO
{
info::aio_reqprio_max
};
/// Conf item to control whether aio is enabled or bypassed.
decltype(ircd::fs::aio::enable)
ircd::fs::aio::enable
{
{ "name", "ircd.fs.aio.enable" },
{ "default", true },
{ "persist", false },
};
/// Global stats structure
decltype(ircd::fs::aio::stats)
ircd::fs::aio::stats;
/// Non-null when aio is available for use
decltype(ircd::fs::aio::system)
ircd::fs::aio::system;
//
// init
//
#ifndef IRCD_USE_AIO
[[gnu::weak]]
ircd::fs::aio::init::init()
{
assert(!system);
}
#endif
#ifndef IRCD_USE_AIO
[[gnu::weak]]
ircd::fs::aio::init::~init()
noexcept
{
assert(!system);
}
#endif
///////////////////////////////////////////////////////////////////////////////
//
// fs/iou.h
//
decltype(ircd::fs::iou::support)
ircd::fs::iou::support
{
#ifdef IRCD_USE_IOU
info::kernel_version[0] > 5 ||
(info::kernel_version[0] >= 5 && info::kernel_version[1] >= 1)
#else
false
#endif
};
/// Conf item to control whether iou is enabled or bypassed.
decltype(ircd::fs::iou::enable)
ircd::fs::iou::enable
{
{ "name", "ircd.fs.iou.enable" },
{ "default", false },
{ "persist", false },
};
/// Global stats structure
decltype(ircd::fs::iou::stats)
ircd::fs::iou::stats;
/// Non-null when iou is available for use
decltype(ircd::fs::iou::system)
ircd::fs::iou::system;
//
// init
//
#ifndef IRCD_USE_IOU
[[gnu::weak]]
ircd::fs::iou::init::init()
{
assert(!system);
}
#endif
#ifndef IRCD_USE_IOU
[[gnu::weak]]
ircd::fs::iou::init::~init()
noexcept
{
assert(!system);
}
#endif
///////////////////////////////////////////////////////////////////////////////
//
// fs/map.h
//
namespace ircd::fs
{
static uint flags(const map::opts &);
static uint prot(const map::opts &);
}
#if defined(MADV_NORMAL) && defined(POSIX_MADV_NORMAL)
static_assert(MADV_NORMAL == POSIX_MADV_NORMAL);
#endif
#if defined(MADV_SEQUENTIAL) && defined(POSIX_MADV_SEQUENTIAL)
static_assert(MADV_SEQUENTIAL == POSIX_MADV_SEQUENTIAL);
#endif
#if defined(MADV_RANDOM) && defined(POSIX_MADV_RANDOM)
static_assert(MADV_RANDOM == POSIX_MADV_RANDOM);
#endif
#if defined(MADV_WILLNEED) && defined(POSIX_MADV_WILLNEED)
static_assert(MADV_WILLNEED == POSIX_MADV_WILLNEED);
#endif
#if defined(MADV_DONTNEED) && defined(POSIX_MADV_DONTNEED)
static_assert(MADV_DONTNEED == POSIX_MADV_DONTNEED);
#endif
size_t
ircd::fs::evict(const map &map,
const size_t &len,
const opts &opts)
{
#if defined(POSIX_MADV_DONTNEED)
return advise(map, POSIX_MADV_DONTNEED, len, opts);
#else
return 0;
#endif
}
size_t
ircd::fs::prefetch(const map &map,
const size_t &len,
const opts &opts)
{
#if defined(POSIX_MADV_WILLNEED)
return advise(map, POSIX_MADV_WILLNEED, len, opts);
#else
return 0;
#endif
}
#if defined(HAVE_MADVISE) && defined(__linux__)
size_t
ircd::fs::advise(const map &map,
const int &advice,
const size_t &len,
const opts &opts)
{
const size_t offset
{
buffer::align(opts.offset, info::page_size)
};
const mutable_buffer buf
{
map + offset, len
};
assert(aligned(data(buf), info::page_size));
switch(const auto res(::madvise(data(buf), size(buf), advice)); res)
{
case 0:
return size(buf); // success
default:
throw_system_error(res); // error
}
__builtin_unreachable();
}
#elif defined(HAVE_POSIX_MADVISE)
size_t
ircd::fs::advise(const map &map,
const int &advice,
const size_t &len,
const opts &opts)
{
const mutable_buffer buf
{
map + opts.offset, len
};
const auto res
{
syscall(::posix_madvise, data(buf), size(buf), advice)
};
return size(buf);
}
#else
#warning "posix_madvise(2) not available for this compilation."
size_t
ircd::fs::advise(const map &map,
const int &advice,
const size_t &len,
const opts &opts)
{
return 0;
}
#endif
//
// map::map
//
ircd::fs::map::map(const fd &fd,
const opts &opts,
const size_t &size)
{
const auto map_size
{
size?: fs::size(fd)
};
void *const &ptr
{
::mmap(nullptr, map_size, prot(opts), flags(opts), int(fd), opts.offset)
};
if(unlikely(ptr == MAP_FAILED))
throw_system_error(errno);
static_cast<mutable_buffer &>(*this) = mutable_buffer
{
reinterpret_cast<char *>(ptr),
map_size
};
const int advise
{
#if defined(HAVE_POSIX_MADVISE)
opts.random? POSIX_MADV_RANDOM:
opts.sequential? POSIX_MADV_SEQUENTIAL:
opts.dontneed? POSIX_MADV_DONTNEED:
#endif
0
};
if(advise)
fs::advise(*this, advise, map_size);
}
ircd::fs::map::~map()
noexcept try
{
if(mutable_buffer::null())
return;
syscall(::munmap, data(*this), size(*this));
}
catch(const std::exception &e)
{
log::critical
{
log, "munmap(%p, %zu) :%s",
data(static_cast<mutable_buffer &>(*this)),
size(static_cast<mutable_buffer &>(*this)),
e.what(),
};
}
ircd::fs::map &
ircd::fs::map::operator=(map &&other)
noexcept
{
auto &ours
{
static_cast<mutable_buffer &>(*this)
};
auto &theirs
{
static_cast<mutable_buffer &>(other)
};
this->~map();
ours = theirs;
theirs = {};
return *this;
}
//
// util
//
uint
ircd::fs::prot(const map::opts &opts)
{
uint ret
{
PROT_NONE
};
if(opts.mode & std::ios::in)
ret |= PROT_READ;
if(opts.mode & std::ios::out)
ret |= PROT_WRITE;
assert(!opts.execute);
if((false) && opts.execute)
ret |= PROT_EXEC;
return ret;
}
uint
ircd::fs::flags(const map::opts &opts)
{
uint ret
{
0
};
if(opts.shared)
ret |= MAP_SHARED;
else
ret |= MAP_PRIVATE;
#if defined(MAP_NONBLOCK)
if(!opts.blocking)
ret |= MAP_NONBLOCK;
#endif
#if defined(MAP_POPULATE)
if(opts.populate)
ret |= MAP_POPULATE;
#endif
#if defined(MAP_NORESERVE)
if(!opts.reserve)
ret |= MAP_NORESERVE;
#endif
return ret;
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/fd.h
//
namespace ircd::fs
{
static uint flags(const fd::opts &);
static uint flags(const std::ios::openmode &);
static long pathconf(const fd &, const int &arg);
}
decltype(ircd::fs::fd::opts::direct_io_enable)
ircd::fs::fd::opts::direct_io_enable
{
{ "name", "ircd.fs.fd.direct_io_enable" },
{ "default", true },
{ "persist", false },
};
#if defined(POSIX_FADV_DONTNEED)
size_t
ircd::fs::evict(const fd &fd,
const size_t &count,
const opts &opts)
{
return advise(fd, POSIX_FADV_DONTNEED, count, opts);
}
#else
#warning "POSIX_FADV_DONTNEED not available on this platform."
size_t
ircd::fs::evict(const fd &fd,
const size_t &count,
const opts &opts)
{
return 0UL;
}
#endif
#if defined(HAVE_POSIX_FADVISE)
size_t
ircd::fs::advise(const fd &fd,
const int &advice,
const size_t &count,
const opts &opts)
{
static const size_t max_count
{
128_KiB
};
size_t i(0), off, cnt; do
{
off = opts.offset + max_count * i++;
cnt = std::min(opts.offset + count - off, max_count);
switch(const auto r(::posix_fadvise(fd, off, cnt, advice)); r)
{
case 0: break;
default: throw_system_error(r);
}
}
while(off + cnt < opts.offset + count);
return count;
}
#else
#warning "posix_fadvise(2) not available for this compilation."
size_t
ircd::fs::advise(const fd &fd,
const int &advice,
const size_t &count,
const opts &opts)
{
return 0UL;
}
#endif
#if defined(HAVE_FCNTL_H) && defined(F_SET_FILE_RW_HINT)
void
ircd::fs::write_life(const fd &fd,
const uint64_t &hint)
{
if(!support::rwh_write_life)
return;
syscall(::fcntl, int(fd), F_SET_FILE_RW_HINT, &hint);
}
#else
#warning "F_SET_FILE_RW_HINT not supported on platform."
void
ircd::fs::write_life(const fd &fd,
const uint64_t &hint)
{
}
#endif
#if defined(HAVE_FCNTL_H) && defined(F_GET_FILE_RW_HINT)
uint64_t
ircd::fs::write_life(const fd &fd)
noexcept try
{
uint64_t ret;
syscall(::fcntl, int(fd), F_GET_FILE_RW_HINT, &ret);
return ret;
}
catch(const std::system_error &e)
{
log::derror
{
log, "fcntl(F_GET_FILE_RW_HINT) fd:%d :%s",
int(fd),
e.what()
};
return 0;
}
#else
#warning "F_GET_FILE_RW_HINT not supported on platform."
uint64_t
ircd::fs::write_life(const fd &fd)
{
return 0UL;
}
#endif
#ifdef HAVE_SYS_STAT_H
ulong
ircd::fs::device(const fd &fd)
{
struct stat st{0};
syscall(::fstat, fd, &st);
return st.st_dev;
}
#else
ulong
ircd::fs::device(const fd &fd)
{
static_assert
(
0, "Please implement this definition"
)
}
#endif
#ifdef HAVE_SYS_STATFS_H
ulong
ircd::fs::fstype(const fd &fd)
{
struct statfs f{0};
syscall(::fstatfs, fd, &f);
return f.f_type;
}
#else
ulong
ircd::fs::fstype(const fd &fd)
{
static_assert
(
0, "Please implement this definition"
)
}
#endif
#ifdef __linux__
size_t
ircd::fs::block_size(const fd &fd)
{
return 512UL;
}
#elif defined(HAVE_SYS_STAT_H)
size_t
ircd::fs::block_size(const fd &fd)
{
struct stat st;
syscall(::fstat, fd, &st);
return st.st_blksize;
}
#else
size_t
ircd::fs::block_size(const fd &fd)
{
return info::page_size;
}
#endif
long
ircd::fs::pathconf(const fd &fd,
const int &arg)
{
return syscall(::fpathconf, fd, arg);
}
size_t
ircd::fs::size(const fd &fd)
{
const off_t cur
{
syscall(::lseek, fd, 0, SEEK_CUR)
};
const off_t end
{
syscall(::lseek, fd, 0, SEEK_END)
};
syscall(::lseek, fd, cur, SEEK_SET);
return end;
}
//
// fd::opts
//
ircd::fs::fd::opts::opts(const std::ios::openmode &mode)
:mode
{
mode
}
,flags
{
fs::flags(mode)
}
,mask
{
flags & O_CREAT?
S_IRUSR | S_IWUSR:
0U
}
,ate
{
bool(mode & std::ios::ate)
}
{
}
//
// fd::fd
//
ircd::fs::fd::fd(const int &fdno)
:fdno
{
fdno
}
{
}
ircd::fs::fd::fd(const string_view &path)
:fd
{
path, opts{}
}
{
}
ircd::fs::fd::fd(const string_view &path,
const opts &opts)
:fd
{
AT_FDCWD, path, opts
}
{
}
ircd::fs::fd::fd(const int &dirfd,
const string_view &path,
const opts &opts)
try
:fdno
{
-1 // sentinel value for inert dtor
}
{
const unwind_exceptional dtor_on_error
{
[this] { this->~fd(); }
};
const mode_t mode
{
mode_t(opts.mask)
};
const uint &flags
{
fs::flags(opts)
};
const int &advise
{
opts.direct?
0:
opts.random?
POSIX_FADV_RANDOM:
opts.sequential?
POSIX_FADV_SEQUENTIAL:
opts.dontneed?
POSIX_FADV_DONTNEED:
0
};
{
const prof::syscall_usage_warning message
{
"fs::fs::fd(): openat(2): %s", path
};
assert((flags & ~O_CREAT) || mode != 0);
fdno = syscall(::openat, dirfd, path_cstr(path), flags, mode);
}
if(advise)
fs::advise(*this, advise);
if(opts.ate)
syscall(::lseek, fdno, 0, SEEK_END);
}
catch(const std::system_error &e)
{
if(opts.errlog)
log::derror
{
log, "`%s' :%s",
path,
e.what(),
};
throw;
}
ircd::fs::fd::fd(fd &&o)
noexcept
:fdno
{
std::move(o.fdno)
}
{
o.fdno = -1;
}
ircd::fs::fd &
ircd::fs::fd::operator=(fd &&o)
noexcept
{
this->~fd();
fdno = std::move(o.fdno);
o.fdno = -1;
return *this;
}
ircd::fs::fd::~fd()
noexcept
{
if(likely(fdno >= 0)) try
{
syscall(::close, fdno);
}
catch(const std::exception &e)
{
log::critical
{
"Failed to close fd:%d :%s",
fdno,
e.what()
};
}
}
int
ircd::fs::fd::release()
noexcept
{
const int fdno(this->fdno);
this->fdno = -1;
return fdno;
}
ircd::fs::fd::opts
ircd::fs::fd::options()
const
{
opts ret;
ret.flags = syscall(::fcntl, int(*this), F_GETFL, 0);
if((ret.flags & O_RDONLY) == O_RDONLY)
ret.mode = std::ios::in;
if((ret.flags & O_WRONLY) == O_WRONLY)
ret.mode = std::ios::out;
if((ret.flags & O_RDWR) == O_RDWR)
ret.mode = std::ios::in | std::ios::out;
if((ret.flags & O_TRUNC) == O_TRUNC)
ret.mode = std::ios::trunc;
ret.direct = ret.flags & O_DIRECT;
ret.cloexec = ret.flags & O_CLOEXEC;
ret.create = ret.flags & O_CREAT;
ret.blocking = ret.flags & O_NONBLOCK;
ret.exclusive = ret.flags & O_EXCL;
return ret;
}
uint
ircd::fs::flags(const fd::opts &opts)
{
uint ret(opts.flags);
ret |= fs::flags(opts.mode);
ret |= opts.direct? O_DIRECT : 0UL;
ret |= opts.cloexec? O_CLOEXEC : 0UL;
ret |= opts.create? O_CREAT : 0UL;
ret |= !opts.blocking? O_NONBLOCK : 0UL;
ret |= opts.exclusive? O_EXCL : 0UL;
return ret;
}
uint
ircd::fs::flags(const std::ios::openmode &mode)
{
static const auto rdwr
{
std::ios::in | std::ios::out
};
uint ret{0};
if((mode & rdwr) == rdwr)
ret |= O_RDWR;
else if(mode & std::ios::out)
ret |= O_WRONLY;
else
ret |= O_RDONLY;
ret |= mode & std::ios::trunc? O_TRUNC : 0;
ret |= mode & std::ios::app? O_APPEND : 0;
ret |= ret & O_WRONLY? O_CREAT : 0;
ret |= ret & O_RDWR && ret & (O_TRUNC | O_APPEND)? O_CREAT : 0;
return ret;
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/opts.h
//
decltype(ircd::fs::opts_default)
ircd::fs::opts_default
{};
decltype(ircd::fs::opts::highest_priority)
ircd::fs::opts::highest_priority
{
std::numeric_limits<decltype(priority)>::min()
};
///////////////////////////////////////////////////////////////////////////////
//
// fs/op.h
//
ircd::string_view
ircd::fs::reflect(const op &op)
{
switch(op)
{
case op::NOOP: return "NOOP";
case op::READ: return "READ";
case op::WRITE: return "WRITE";
case op::SYNC: return "SYNC";
case op::WAIT: return "WAIT";
}
return "????";
}
#ifndef IRCD_USE_AIO
[[gnu::weak]]
ircd::fs::op
ircd::fs::aio::translate(const int &val)
{
return op::NOOP;
}
#endif
#ifndef IRCD_USE_IOU
[[gnu::weak]]
ircd::fs::op
ircd::fs::iou::translate(const int &val)
{
return op::NOOP;
}
#endif
///////////////////////////////////////////////////////////////////////////////
//
// fs/iov.h
//
ircd::fs::const_iovec_view
ircd::fs::make_iov(const iovec_view &iov,
const mutable_buffers &bufs,
const size_t &offset)
{
assert(offset <= buffers::size(bufs));
const size_t max
{
std::min(iov.size(), bufs.size())
};
size_t i(0), off(0);
for(; i < max; off += size(bufs[i++]))
if(size(bufs[i]) >= offset - off)
{
assert(offset >= off);
off = offset - off;
break;
}
assert(i <= max);
if(i < max)
{
assert(off <= size(bufs[i]));
iov.at(i) =
{
data(bufs[i]) + off, size(bufs[i]) - off
};
for(++i; i < max; ++i)
iov.at(i) =
{
data(bufs[i]), size(bufs[i])
};
}
assert(i <= max);
const const_iovec_view ret{iov.data(), i};
assert(bytes(ret) <= buffer::buffers::size(bufs));
return ret;
}
ircd::fs::const_iovec_view
ircd::fs::make_iov(const iovec_view &iov,
const const_buffers &bufs,
const size_t &offset)
{
assert(offset <= buffers::size(bufs));
const size_t max
{
std::min(iov.size(), bufs.size())
};
size_t i(0), off(0);
for(; i < max; off += size(bufs[i++]))
if(size(bufs[i]) >= offset - off)
{
assert(offset >= off);
off = offset - off;
break;
}
assert(i <= max);
if(i < max)
{
assert(off <= size(bufs[i]));
iov.at(i) =
{
const_cast<char *>(data(bufs[i])) + off, size(bufs[i]) - off
};
for(++i; i < max; ++i)
iov.at(i) =
{
const_cast<char *>(data(bufs[i])), size(bufs[i])
};
}
assert(i <= max);
const const_iovec_view ret{iov.data(), i};
assert(bytes(ret) <= buffer::buffers::size(bufs));
return ret;
}
size_t
ircd::fs::bytes(const const_iovec_view &iov)
{
return std::accumulate(begin(iov), end(iov), size_t(0), []
(auto ret, const auto &iov)
{
return ret += iov.iov_len;
});
}
///////////////////////////////////////////////////////////////////////////////
//
// fs/error.h
//
std::string
ircd::string(const boost::filesystem::filesystem_error &e)
{
return ircd::string(512, [&e]
(const mutable_buffer &buf)
{
return string(buf, e);
});
}
ircd::string_view
ircd::string(const mutable_buffer &buf,
const boost::filesystem::filesystem_error &e)
{
return fmt::sprintf
{
buf, "%s :%s", e.code().category().name(), e.what()
};
}
std::system_error
ircd::make_system_error(const boost::filesystem::filesystem_error &e)
{
return std::system_error
{
make_error_code(e), e.what()
};
}
std::error_code
ircd::make_error_code(const boost::filesystem::filesystem_error &e)
{
const boost::system::error_code &ec
{
e.code()
};
return make_error_code(ec);
}
//
// error::error
//
decltype(ircd::fs::error::buf) thread_local
ircd::fs::error::buf;
ircd::fs::error::error(const boost::filesystem::filesystem_error &e)
:std::system_error
{
make_system_error(e)
}
{
}
///////////////////////////////////////////////////////////////////////////////
//
// Internal utils
//
/// Translate an ircd::fs opts priority integer to an AIO priority integer.
/// The ircd::fs priority integer is like a nice value. The AIO value is
/// positive [0, MAX_REQPRIO]. This function takes an ircd::fs value and
/// shifts it to the AIO value.
int
ircd::fs::reqprio(int input)
noexcept
{
const auto &max_reqprio
{
aio::MAX_REQPRIO
};
static const auto median
{
int(max_reqprio / 2)
};
input = std::max(input, 0 - median);
input = std::min(input, median);
input = max_reqprio - (input + median);
assert(input >= 0 && input <= int(max_reqprio));
return input;
}