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construct/ircd/server.cc
2019-03-01 10:07:56 -08:00

3381 lines
67 KiB
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 <ircd/asio.h>
namespace ircd::server
{
// Internal state
ctx::dock dock; // internal semaphore
// Internal util
template<class F> size_t accumulate_peers(F&&);
template<class F> size_t accumulate_links(F&&);
template<class F> size_t accumulate_tags(F&&);
// Internal control
std::unique_ptr<peer> create(const net::hostport &);
}
decltype(ircd::server::log)
ircd::server::log
{
"server", 'S'
};
ircd::conf::item<ircd::seconds>
close_all_timeout
{
{ "name", "ircd.server.close_all_timeout" },
{ "default", 2L },
};
//
// init
//
ircd::server::init::init()
{
}
ircd::server::init::~init()
noexcept
{
interrupt_all();
close_all();
wait_all();
log::debug
{
log, "All server peers, connections, and requests are clear."
};
}
//
// server
//
void
ircd::server::wait_all()
{
while(peer_unfinished())
{
if(dock.wait_for(seconds(2)))
continue;
log::warning
{
log, "Waiting for %zu tags on %zu links on %zu of %zu peers to close...",
tag_count(),
link_count(),
peer_unfinished(),
peer_count()
};
}
peers.clear();
}
void
ircd::server::close_all()
{
log::debug
{
log, "Closing all %zu peers",
peer_count()
};
net::close_opts opts;
opts.timeout = seconds(close_all_timeout);
for(auto &peer : peers)
peer.second->close(opts);
}
void
ircd::server::interrupt_all()
{
log::debug
{
log, "Interrupting %zu tags on %zu links on %zu peers",
tag_count(),
link_count(),
peer_count()
};
for(auto &peer : peers)
peer.second->cancel();
}
ircd::server::peer &
ircd::server::get(const net::hostport &hostport)
{
thread_local char canonbuf[512];
const auto canonized
{
net::canonize(canonbuf, hostport)
};
auto it(peers.lower_bound(canonized));
if(it == peers.end() || it->first != canonized)
{
auto peer
{
create(hostport)
};
log::debug
{
log, "peer(%p) for %s created; adding...",
peer.get(),
canonized
};
const string_view key{peer->hostcanon};
it = peers.emplace_hint(it, key, std::move(peer));
assert(it->second->hostcanon.data() == it->first.data());
assert(key == canonized);
}
return *it->second;
}
std::unique_ptr<ircd::server::peer>
ircd::server::create(const net::hostport &hostport)
{
auto peer
{
std::make_unique<server::peer>(hostport)
};
// Async DNS resolve. The links for the new peer will be connected
// once the resolver calls back into peer::handle_resolve().
peer->resolve(peer->open_opts.hostport);
return peer;
}
ircd::server::peer &
ircd::server::find(const net::hostport &hostport)
{
return *peers.at(host(hostport));
}
bool
ircd::server::exists(const net::hostport &hostport)
{
return peers.find(host(hostport)) != end(peers);
}
bool
ircd::server::errclear(const net::hostport &hostport)
{
const auto it
{
peers.find(host(hostport))
};
if(it == end(peers))
return false;
auto &peer(*it->second);
return peer.err_clear();
}
ircd::string_view
ircd::server::errmsg(const net::hostport &hostport)
{
const auto it
{
peers.find(host(hostport))
};
if(it == end(peers))
return {};
return it->second->err_msg();
}
size_t
ircd::server::peer_unfinished()
{
return accumulate_peers([]
(const auto &peer)
{
return !peer.finished();
});
}
size_t
ircd::server::peer_count()
{
return peers.size();
}
size_t
ircd::server::link_count()
{
return accumulate_peers([]
(const auto &peer)
{
return peer.link_count();
});
}
size_t
ircd::server::tag_count()
{
return accumulate_peers([]
(const auto &peer)
{
return peer.tag_count();
});
}
template<class F>
size_t
ircd::server::accumulate_tags(F&& closure)
{
return accumulate_links([&closure]
(const auto &link)
{
return link.accumulate_tags(std::forward<F>(closure));
});
}
template<class F>
size_t
ircd::server::accumulate_links(F&& closure)
{
return accumulate_peers([&closure]
(const auto &peer)
{
return peer.accumulate_links(std::forward<F>(closure));
});
}
template<class F>
size_t
ircd::server::accumulate_peers(F&& closure)
{
return std::accumulate(begin(peers), end(peers), size_t(0), [&closure]
(auto ret, const auto &pair)
{
const auto &peer{*pair.second};
return ret += closure(peer);
});
}
///
// request
//
decltype(ircd::server::request::opts_default)
ircd::server::request::opts_default
{};
/// Canceling a request is tricky. This allows a robust way to let the user's
/// request go out of scope at virtually any time without disrupting the
/// pipeline and other requests.
bool
ircd::server::cancel(request &request)
{
if(!request.tag)
return false;
if(request.tag->canceled())
return false;
if(request.tag->abandoned())
return false;
auto &tag
{
*request.tag
};
/*
log::debug
{
log, "cancel request(%p) tag(%p) commit:%d w:%zu hr:%zu cr:%zu",
&request,
&tag,
tag.committed(),
tag.state.written,
tag.state.head_read,
tag.state.content_read
};
*/
tag.set_exception(canceled
{
"Request canceled"
});
// We got off easy... The link's write loop won't start an abandoned
// request. All that has to be done is indicate a full cancellation
// immediately and the user will know nothing was revealed to the remote.
if(!tag.committed())
return true;
// Now things aren't so easy. More complicated logic happens inside...
cancel(request, tag);
return true;
}
void
ircd::server::submit(const hostport &hostport,
request &request)
{
if(unlikely(ircd::run::level != ircd::run::level::RUN))
throw unavailable
{
"Unable to fulfill requests at this time."
};
assert(request.tag == nullptr);
auto &peer(server::get(hostport));
peer.submit(request);
}
///////////////////////////////////////////////////////////////////////////////
//
// server/peer.h
//
decltype(ircd::server::peers)
ircd::server::peers
{};
decltype(ircd::server::peer::link_min_default)
ircd::server::peer::link_min_default
{
{ "name", "ircd.server.peer.link_min" },
{ "default", 1L }
};
decltype(ircd::server::peer::link_max_default)
ircd::server::peer::link_max_default
{
{ "name", "ircd.server.peer.link_max" },
{ "default", 2L }
};
//
// peer::peer
//
ircd::server::peer::peer(const net::hostport &hostport,
const net::open_opts &open_opts)
:hostcanon
{
net::canonize(hostport)
}
,service
{
net::service(hostport)
}
,open_opts
{
std::move(open_opts)
}
{
const net::hostport canon{this->hostcanon};
this->open_opts.hostport.host = net::host(canon);
this->open_opts.hostport.port = net::port(canon);
this->open_opts.hostport.service = this->service;
this->open_opts.ipport = this->remote;
}
ircd::server::peer::~peer()
noexcept
{
assert(links.empty());
}
void
ircd::server::peer::close(const net::close_opts &opts)
{
op_fini = true;
link *links[LINK_MAX];
const auto end(pointers(this->links, links));
for(link **link(links); link != end; ++link)
(*link)->close(opts);
if(finished())
return handle_finished();
}
void
ircd::server::peer::cancel()
{
for(auto &link : this->links)
link.cancel_all(std::make_exception_ptr(canceled
{
"Request was aborted due to interruption."
}));
}
bool
ircd::server::peer::err_clear()
{
const auto ret{bool(e)};
e.reset(nullptr);
op_fini = false;
return ret;
}
template<class... A>
void
ircd::server::peer::err_set(A&&... args)
{
this->e = std::make_unique<err>(std::forward<A>(args)...);
}
ircd::string_view
ircd::server::peer::err_msg()
const
{
return bool(e)? what(e->eptr) : string_view{};
}
bool
ircd::server::peer::err_has()
const
{
return bool(e);
}
decltype(ircd::server::peer::error_clear_default)
ircd::server::peer::error_clear_default
{
{ "name", "ircd.server.peer.error.clear_default" },
{ "default", 305L }
};
bool
ircd::server::peer::err_check()
{
if(op_fini)
return false;
if(!err_has())
return true;
//TODO: The specific error type should be switched and finer
//TODO: timeouts should be used depending on the error: i.e
//TODO: NXDOMAIN vs. temporary conn timeout, etc.
if(e->etime + seconds(error_clear_default) > now<system_point>())
return false;
err_clear();
return true;
}
void
ircd::server::peer::submit(request &request)
try
{
if(!err_check() || unlikely(ircd::run::level != ircd::run::level::RUN))
throw unavailable
{
"Peer is unable to take any requests: %s", err_msg()
};
link *const ret
{
link_get(request)
};
if(likely(ret))
{
ret->submit(request);
return;
}
if(!request.tag)
throw unavailable
{
"No link to peer %s available", hostcanon
};
else
request.tag->set_exception(unavailable
{
"No link to peer %s available", hostcanon
});
}
catch(const std::exception &e)
{
if(!request.tag)
throw;
const auto eptr(std::current_exception());
const ctx::exception_handler eh;
request.tag->set_exception(eptr);
}
/// Dispatch algorithm here; finds the best link to place this request on,
/// or creates a new link entirely. There are a number of factors: foremost
/// if any special needs are indicated,
//
ircd::server::link *
ircd::server::peer::link_get(const request &request)
{
assert(request.opt);
const auto &prio(request.opt->priority);
if(links.empty())
return &link_add(1);
// Indicates that we can't add anymore links for this peer and the rest
// of the algorithm should consider this.
const bool links_maxed
{
links.size() >= link_max()
};
link *best{nullptr};
for(auto &cand : links)
{
// Don't want a link that's shutting down or marked for exclusion
if(cand.op_fini || cand.exclude)
continue;
if(!best)
{
best = &cand;
continue;
}
// Indicates that the best candidate has its pipe saturated which can
// be factored into the comparisons here.
const bool best_maxed
{
best->tag_committed() >= best->tag_commit_max()
};
const bool cand_maxed
{
cand.tag_committed() >= cand.tag_commit_max()
};
if(best_maxed && !cand_maxed)
{
best = &cand;
continue;
}
if(!best_maxed && cand_maxed)
continue;
// Candidates's queue has less or same backlog of unsent requests, but
// now measure if candidate will take longer to process at least the
// write-side of those requests.
if(cand.write_remaining() > best->write_remaining())
continue;
// Candidate might be working through really large content; though
// this is a very sketchy measurement right now since we only *might*
// know about content-length for the *one* active tag occupying the
// socket.
if(cand.read_remaining() > best->read_remaining())
continue;
// Coarse distribution based on who has more work; this is weak, should
// be replaced.
if(cand.tag_count() > best->tag_count())
continue;
best = &cand;
}
// Even though the prio is set to the super special value we allow the
// normal loop to first come up with a best link which already is open
// rather than unconditionally opening a new connection.
if(prio == std::numeric_limits<std::remove_reference<decltype(prio)>::type>::min())
{
if(!best)
return &link_add(1);
if(best->tag_committed())
return &link_add(1);
return best;
}
if(links_maxed)
return best;
// best might not be good enough, we could try another connection. If best
// has a backlog or is working on a large download or slow request.
if(!best)
{
best = &link_add();
return best;
}
if(best->tag_uncommitted() < best->tag_commit_max())
return best;
best = &link_add();
return best;
}
ircd::server::link &
ircd::server::peer::link_add(const size_t &num)
{
assert(!finished());
if(e)
{
std::rethrow_exception(e->eptr);
__builtin_unreachable();
}
assert(!op_fini);
links.emplace_back(*this);
auto &link{links.back()};
if(remote)
link.open(open_opts);
return link;
}
void
ircd::server::peer::handle_open(link &link,
std::exception_ptr eptr)
{
if(eptr)
{
if(links.size() == 1)
err_set(eptr);
log::derror
{
log, "peer(%p) link(%p) [%s]: open: %s",
this,
&link,
string(remote),
what(eptr)
};
if(op_fini)
{
if(link.finished())
handle_finished(link);
return;
}
link.close(net::dc::RST);
return;
}
}
void
ircd::server::peer::handle_close(link &link,
std::exception_ptr eptr)
{
if(eptr)
log::derror
{
log, "peer(%p) link(%p) [%s]: close: %s",
this,
&link,
string(remote),
what(eptr)
};
if(link.finished())
handle_finished(link);
}
void
ircd::server::peer::handle_error(link &link,
std::exception_ptr eptr)
{
assert(bool(eptr));
link.cancel_committed(eptr);
log::derror
{
log, "peer(%p) link(%p): %s",
this,
&link,
what(eptr)
};
link.close(net::dc::RST);
}
void
ircd::server::peer::handle_error(link &link,
const std::system_error &e)
{
using std::errc;
using boost::asio::error::get_misc_category;
const auto &ec{e.code()};
if(system_category(ec)) switch(ec.value())
{
case 0:
assert(0);
break;
default:
break;
}
else if(ec.category() == get_misc_category()) switch(ec.value())
{
case asio::error::eof:
log::debug
{
log, "peer(%p) link(%p) [%s]: %s",
this,
&link,
string(remote),
e.what()
};
link.close(net::close_opts_default);
return;
default:
break;
}
log::derror
{
log, "peer(%p) link(%p) [%s]: %s",
this,
&link,
string(remote),
e.what()
};
link.cancel_committed(std::make_exception_ptr(e));
link.close(net::dc::RST);
}
void
ircd::server::peer::handle_finished(link &link)
{
assert(link.finished());
del(link);
if(finished())
handle_finished();
}
/// This is where we're notified a tag has been completed either to start the
/// next request when the link has too many requests in flight or perhaps to
/// reschedule the queues in various links to diffuse the pending requests.
/// This can't throw because the link still has to remove this tag from its
/// queue.
void
ircd::server::peer::handle_tag_done(link &link,
tag &tag)
noexcept try
{
log::debug
{
log, "peer(%p) link(%p) tag(%p) done wt:%zu rt:%zu hr:%zu cr:%zu cl:%zu; %zu more in queue",
this,
&link,
&tag,
tag.write_size(),
tag.read_size(),
tag.state.head_read,
tag.state.content_read,
tag.state.content_length,
link.tag_count() - 1
};
if(link.tag_committed() >= link.tag_commit_max())
link.wait_writable();
}
catch(const std::exception &e)
{
log::critical
{
log, "peer(%p) link(%p) tag(%p) done; %s",
this,
&link,
&tag,
e.what()
};
}
/// This is where we're notified a link has processed its queue and has no
/// more work. We can choose whether to close the link or keep it open and
/// reinstate the read poll; reschedule other work to this link, etc.
void
ircd::server::peer::handle_link_done(link &link)
{
assert(link.tag_count() == 0);
if(link_ready() > link_min())
{
link.close();
return;
}
link.wait_readable();
}
/// This is called when a tag on a link receives an HTTP response head.
/// We can use this to learn information from the tag's request and the
/// response head etc.
void
ircd::server::peer::handle_head_recv(const link &link,
const tag &tag,
const http::response::head &head)
{
// Learn the software version of the remote peer so we can shape
// requests more effectively.
if(!server_name && head.server)
{
server_name = std::string{head.server};
log::debug
{
log, "peer(%p) learned %s is '%s'",
this,
string(remote),
server_name
};
}
}
void
ircd::server::peer::disperse(link &link)
{
disperse_uncommitted(link);
link.cancel_committed(std::make_exception_ptr(canceled
{
"Request was aborted; though it was partially completed"
}));
assert(link.queue.empty());
}
void
ircd::server::peer::disperse_uncommitted(link &link)
{
auto &queue(link.queue);
auto it(begin(queue));
while(it != end(queue)) try
{
auto &tag{*it};
if(!tag.request || tag.committed())
{
++it;
continue;
}
submit(*tag.request);
it = queue.erase(it);
}
catch(const std::exception &e)
{
const auto &tag{*it};
log::warning
{
log, "peer(%p) failed to resubmit tag(%p): %s",
this,
&tag,
e.what()
};
it = queue.erase(it);
}
}
/// This *cannot* be called unless a link's socket is closed and its queue
/// is empty. It is usually only called by a disconnect handler because
/// the proper way to remove a link is asynchronously through link.close();
void
ircd::server::peer::del(link &link)
{
assert(!link.tag_count());
assert(!link.opened());
const auto it(std::find_if(begin(links), end(links), [&link]
(const auto &link_)
{
return &link_ == &link;
}));
assert(it != end(links));
log::debug
{
log, "peer(%p) removing link(%p) %zu of %zu to %s",
this,
&link,
std::distance(begin(links), it),
links.size(),
string(remote)
};
links.erase(it);
}
void
ircd::server::peer::resolve(const hostport &hostport)
{
if(op_resolve || op_fini)
return;
auto handler
{
std::bind(&peer::handle_resolve, this, ph::_1, ph::_2, ph::_3)
};
op_resolve = true;
net::dns::resolve(hostport, std::move(handler));
}
void
ircd::server::peer::handle_resolve(std::exception_ptr eptr,
const hostport &,
const ipport &ipport)
try
{
const ctx::critical_assertion ca;
assert(op_resolve);
op_resolve = false;
if(eptr)
{
err_set(eptr);
std::rethrow_exception(eptr);
__builtin_unreachable();
}
// Save the results of the query to this object instance.
this->remote = ipport;
open_opts.ipport = this->remote;
port(open_opts.hostport) = port(ipport);
// The hostname in open_opts should still reference this object's string.
assert(host(open_opts.hostport).data() == this->hostcanon.data());
if(unlikely(ircd::run::level != ircd::run::level::RUN))
op_fini = true;
if(unlikely(finished()))
return handle_finished();
if(op_fini)
return;
link *links[LINK_MAX];
const auto end(pointers(this->links, links));
for(link **link(links); link != end; ++link)
(*link)->open(open_opts);
}
catch(const std::exception &e)
{
log::derror
{
log, "peer(%p): %s",
this,
e.what()
};
close();
}
void
ircd::server::peer::handle_finished()
{
assert(finished());
// Right now this is what the server:: ~init sequence needs
// to wait for all links to close on IRCd shutdown.
server::dock.notify_all();
}
size_t
ircd::server::peer::read_total()
const
{
return read_bytes;
}
size_t
ircd::server::peer::write_total()
const
{
return write_bytes;
}
size_t
ircd::server::peer::read_remaining()
const
{
return accumulate_links([](const auto &link)
{
return link.read_remaining();
});
}
size_t
ircd::server::peer::read_completed()
const
{
return accumulate_links([](const auto &link)
{
return link.read_completed();
});
}
size_t
ircd::server::peer::read_size()
const
{
return accumulate_links([](const auto &link)
{
return link.read_size();
});
}
size_t
ircd::server::peer::write_remaining()
const
{
return accumulate_links([](const auto &link)
{
return link.write_remaining();
});
}
size_t
ircd::server::peer::write_completed()
const
{
return accumulate_links([](const auto &link)
{
return link.write_completed();
});
}
size_t
ircd::server::peer::write_size()
const
{
return accumulate_links([](const auto &link)
{
return link.write_size();
});
}
size_t
ircd::server::peer::tag_uncommitted()
const
{
return accumulate_links([](const auto &link)
{
return link.tag_uncommitted();
});
}
size_t
ircd::server::peer::tag_committed()
const
{
return accumulate_links([](const auto &link)
{
return link.tag_committed();
});
}
size_t
ircd::server::peer::tag_count()
const
{
return accumulate_links([](const auto &link)
{
return link.tag_count();
});
}
size_t
ircd::server::peer::link_ready()
const
{
return accumulate_links([](const auto &link)
{
return link.ready();
});
}
size_t
ircd::server::peer::link_busy()
const
{
return accumulate_links([](const auto &link)
{
return link.busy();
});
}
size_t
ircd::server::peer::link_count()
const
{
return links.size();
}
size_t
ircd::server::peer::link_min()
const
{
return link_min_default;
}
size_t
ircd::server::peer::link_max()
const
{
return link_max_default;
}
bool
ircd::server::peer::finished()
const
{
return links.empty() && !op_resolve && op_fini;
}
template<class F>
size_t
ircd::server::peer::accumulate_tags(F&& closure)
const
{
return accumulate_links([&closure](const auto &link)
{
return link.accumulate([&closure](const auto &tag)
{
return closure(tag);
});
});
}
template<class F>
size_t
ircd::server::peer::accumulate_links(F&& closure)
const
{
return std::accumulate(begin(links), end(links), size_t(0), [&closure]
(auto ret, const auto &tag)
{
return ret += closure(tag);
});
}
//
// peer::err
//
ircd::server::peer::err::err(std::exception_ptr eptr)
:eptr{std::move(eptr)}
,etime{now<system_point>()}
{
}
ircd::server::peer::err::~err()
noexcept
{
}
//
// link
//
decltype(ircd::server::link::tag_max_default)
ircd::server::link::tag_max_default
{
{ "name", "ircd.server.link.tag_max" },
{ "default", -1L }
};
decltype(ircd::server::link::tag_commit_max_default)
ircd::server::link::tag_commit_max_default
{
{ "name", "ircd.server.link.tag_commit_max" },
{ "default", 3L }
};
//
// link::link
//
ircd::server::link::link(server::peer &peer)
:peer{&peer}
{
}
ircd::server::link::~link()
noexcept
{
assert(!busy());
assert(!opened());
}
void
ircd::server::link::submit(request &request)
{
assert(!request.tag || !request.tag->committed());
const auto it
{
request.tag? queue.emplace(end(queue), std::move(*request.tag)):
queue.emplace(end(queue), request)
};
/*
log::debug
{
log, "tag(%p) submitted to link(%p) queue: %zu",
&(*it),
this,
tag_count()
};
*/
if(ready())
wait_writable();
}
void
ircd::server::link::cancel_all(std::exception_ptr eptr)
{
for(auto it(begin(queue)); it != end(queue); it = queue.erase(it))
{
auto &tag{*it};
if(!tag.request)
continue;
tag.set_exception(eptr);
}
}
void
ircd::server::link::cancel_committed(std::exception_ptr eptr)
{
for(auto it(begin(queue)); it != end(queue); it = queue.erase(it))
{
auto &tag{*it};
if(!tag.request)
continue;
if(!tag.committed())
break;
tag.set_exception(eptr);
}
}
void
ircd::server::link::cancel_uncommitted(std::exception_ptr eptr)
{
auto it(begin(queue));
while(it != end(queue))
{
auto &tag{*it};
if(!tag.request || tag.committed())
{
++it;
continue;
}
tag.set_exception(eptr);
it = queue.erase(it);
}
}
bool
ircd::server::link::open(const net::open_opts &open_opts)
{
assert(ircd::run::level == ircd::run::level::RUN);
if(op_init)
return false;
auto handler
{
std::bind(&link::handle_open, this, ph::_1)
};
op_init = true;
const unwind::exceptional unhandled{[this]
{
op_init = false;
}};
socket = net::open(open_opts, std::move(handler));
return true;
}
void
ircd::server::link::handle_open(std::exception_ptr eptr)
{
assert(op_init);
op_init = false;
if(!eptr && !op_fini)
wait_writable();
if(peer)
peer->handle_open(*this, std::move(eptr));
}
bool
ircd::server::link::close(const net::close_opts &close_opts)
{
if(op_fini)
return false;
op_fini = true;
// Tell the peer to ditch everything in the queue; op_fini has been set so
// the tags won't get assigned back to this link.
if(tag_count() && peer)
peer->disperse(*this);
auto handler
{
std::bind(&link::handle_close, this, ph::_1)
};
if(!socket)
{
handler(std::exception_ptr{});
return true;
}
net::close(*socket, close_opts, std::move(handler));
return true;
}
void
ircd::server::link::handle_close(std::exception_ptr eptr)
{
assert(op_fini);
if(op_init)
{
assert(bool(eptr));
}
if(peer)
peer->handle_close(*this, std::move(eptr));
}
void
ircd::server::link::wait_writable()
{
if(op_write || unlikely(op_fini))
return;
auto handler
{
std::bind(&link::handle_writable, this, ph::_1)
};
assert(ready());
op_write = true;
const unwind::exceptional unhandled{[this]
{
op_write = false;
}};
net::wait(*socket, net::ready::WRITE, std::move(handler));
}
void
ircd::server::link::handle_writable(const error_code &ec)
try
{
using std::errc;
op_write = false;
if(unlikely(finished()))
{
assert(peer);
return peer->handle_finished(*this);
}
if(system_category(ec)) switch(ec.value())
{
case 0:
handle_writable_success();
return;
case int(errc::operation_canceled):
return;
default:
break;
}
throw std::system_error{ec};
}
catch(const std::system_error &e)
{
assert(peer);
peer->handle_error(*this, e);
}
catch(...)
{
assert(peer);
peer->handle_error(*this, std::current_exception());
}
void
ircd::server::link::handle_writable_success()
{
auto it(begin(queue));
while(it != end(queue))
{
auto &tag{*it};
if((tag.abandoned() || tag.canceled()) && !tag.committed())
{
log::debug
{
log, "link(%p) discarding canceled:%d abandoned:%d uncommitted tag %zu of %zu",
this,
tag.canceled(),
tag.abandoned(),
tag_committed(),
tag_count()
};
it = queue.erase(it);
continue;
}
if(tag.canceled() && tag.committed() && tag_committed() <= 1)
{
log::debug
{
log, "link(%p) closing to interrupt canceled committed tag(%p) of %zu",
this,
&tag,
tag_count()
};
close();
break;
}
if(tag_committed() == 0)
wait_readable();
if(!process_write(tag))
{
wait_writable();
break;
}
// Limits the amount of requests in the pipe.
if(tag_committed() >= tag_commit_max())
break;
++it;
}
}
bool
ircd::server::link::process_write(tag &tag)
{
if(!tag.committed())
log::debug
{
log, "peer(%p) link(%p) starting on tag(%p) %zu of %zu: wt:%zu",
peer,
this,
&tag,
tag_committed(),
tag_count(),
tag.write_size()
};
while(tag.write_remaining())
{
const const_buffer buffer
{
tag.make_write_buffer()
};
assert(!empty(buffer));
const const_buffer written
{
process_write_next(buffer)
};
tag.wrote_buffer(written);
assert(tag_committed() <= tag_commit_max());
if(size(written) < size(buffer))
return false;
}
return true;
}
ircd::const_buffer
ircd::server::link::process_write_next(const const_buffer &buffer)
{
const size_t bytes
{
write_any(*socket, buffer)
};
const const_buffer written
{
data(buffer), bytes
};
assert(peer);
peer->write_bytes += bytes;
return written;
}
void
ircd::server::link::wait_readable()
{
if(op_read || op_fini)
return;
assert(ready());
op_read = true;
const unwind::exceptional unhandled{[this]
{
op_read = false;
}};
auto handler
{
std::bind(&link::handle_readable, this, ph::_1)
};
net::wait(*socket, net::ready::READ, std::move(handler));
}
void
ircd::server::link::handle_readable(const error_code &ec)
try
{
using std::errc;
op_read = false;
if(unlikely(finished()))
{
assert(peer);
return peer->handle_finished(*this);
}
if(system_category(ec)) switch(ec.value())
{
case 0:
handle_readable_success();
return;
case int(errc::operation_canceled):
return;
default:
break;
}
throw std::system_error{ec};
}
catch(const std::system_error &e)
{
assert(peer);
peer->handle_error(*this, e);
}
catch(...)
{
assert(peer);
peer->handle_error(*this, std::current_exception());
}
/// Process as many read operations from as many tags as possible
void
ircd::server::link::handle_readable_success()
{
if(queue.empty())
{
discard_read();
wait_readable();
return;
}
// Data pointed to by overrun will remain intact between iterations
// because this loop isn't executing in any ircd::ctx.
const_buffer overrun; do
{
if(!process_read(overrun))
{
wait_readable();
return;
}
}
while(!queue.empty());
assert(peer);
peer->handle_link_done(*this);
}
/// Process as many read operations for one tag as possible
bool
ircd::server::link::process_read(const_buffer &overrun)
try
{
auto &tag
{
queue.front()
};
if(!tag.committed())
{
// Tag hasn't sent its data yet, we shouldn't have anything for it
assert(empty(overrun));
discard_read(); // Should stumble on a socket error.
return false;
}
if(tag.canceled() && tag_committed() <= 1)
{
log::debug
{
log, "link(%p) closing to interrupt canceled committed tag(%p) of %zu",
this,
&tag,
tag_count()
};
close();
return false;
}
bool done{false}; do
{
overrun = process_read_next(overrun, tag, done);
}
while(!done);
assert(peer);
peer->handle_tag_done(*this, tag);
assert(!queue.empty());
queue.pop_front();
return true;
}
catch(const buffer_overrun &e)
{
queue.pop_front();
throw;
}
catch(const std::system_error &e)
{
using std::errc;
if(system_category(e.code())) switch(e.code().value())
{
case 0:
assert(0);
return true;
case int(errc::resource_unavailable_try_again):
return false;
default:
break;
}
throw;
}
/// Process one read operation for one tag
ircd::const_buffer
ircd::server::link::process_read_next(const const_buffer &underrun,
tag &tag,
bool &done)
try
{
const mutable_buffer buffer
{
tag.make_read_buffer()
};
const size_t copied
{
copy(buffer, underrun)
};
const mutable_buffer remaining
{
data(buffer) + copied, size(buffer) - copied
};
const const_buffer view
{
read(remaining)
};
const const_buffer overrun
{
tag.read_buffer(view, done, *this)
};
assert(done || empty(overrun));
return overrun;
}
catch(const buffer_overrun &e)
{
tag.set_exception(e);
throw;
}
/// Read directly off the link's socket into buf
ircd::const_buffer
ircd::server::link::read(const mutable_buffer &buf)
{
assert(!empty(buf));
const size_t received
{
read_one(*socket, buf)
};
assert(peer);
peer->read_bytes += received;
assert(received);
return const_buffer
{
data(buf), received
};
}
void
ircd::server::link::discard_read()
{
assert(socket);
ssize_t discard
{
SSL_pending(socket->ssl.native_handle())
};
if(discard <= 0 && queue.empty())
discard = available(*socket);
if(discard <= 0 && !queue.empty())
discard = 1;
const size_t discarded
{
discard_any(*socket, size_t(discard))
};
assert(peer);
peer->read_bytes += discarded;
// Shouldn't ever be hit because the read() within discard() throws
// the pending error like an eof.
const fmt::snstringf msg
{
512, "peer(%p %s) link(%p q:%zu) socket(%s) discarded %zu of %zd unexpected bytes",
peer,
peer?
peer->hostcanon:
std::string{},
this,
queue.size(),
likely(peer)?
string(peer->remote):
socket?
string(remote_ipport(*socket)):
std::string{},
discarded,
discard
};
log::warning
{
log, "%s", string_view{msg}
};
// just in case so this doesn't get loopy with discarding zero with
// an empty queue...
if(unlikely(!discard && !discarded))
throw panic
{
"%s", string_view{msg}
};
}
size_t
ircd::server::link::tag_uncommitted()
const
{
return tag_count() - tag_committed();
}
size_t
ircd::server::link::tag_committed()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.committed();
});
}
size_t
ircd::server::link::tag_count()
const
{
return queue.size();
}
size_t
ircd::server::link::read_total()
const
{
return socket? socket->in.bytes : 0;
}
size_t
ircd::server::link::write_total()
const
{
return socket? socket->out.bytes : 0;
}
size_t
ircd::server::link::read_remaining()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.read_remaining();
});
}
size_t
ircd::server::link::read_completed()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.read_completed();
});
}
size_t
ircd::server::link::read_size()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.read_size();
});
}
size_t
ircd::server::link::write_remaining()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.write_remaining();
});
}
size_t
ircd::server::link::write_completed()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.write_completed();
});
}
size_t
ircd::server::link::write_size()
const
{
return accumulate_tags([](const auto &tag)
{
return tag.write_size();
});
}
bool
ircd::server::link::busy()
const
{
return !queue.empty();
}
bool
ircd::server::link::ready()
const
{
return opened() && !op_init && !op_fini;
}
bool
ircd::server::link::opened()
const noexcept
{
return bool(socket) && net::opened(*socket);
}
bool
ircd::server::link::finished()
const
{
if(!bool(socket))
return true;
return !opened() && op_fini && !op_init && !op_write && !op_read;
}
size_t
ircd::server::link::tag_commit_max()
const
{
return tag_commit_max_default;
}
size_t
ircd::server::link::tag_max()
const
{
return tag_max_default;
}
template<class F>
size_t
ircd::server::link::accumulate_tags(F&& closure)
const
{
return std::accumulate(begin(queue), end(queue), size_t(0), [&closure]
(auto ret, const auto &tag)
{
return ret += closure(tag);
});
}
//
// tag
//
/// This is tricky. When a user cancels a request which has committed some
/// writes to the remote we have to continue to service it through to
/// completion without disrupting the linearity of the link's pipeline
/// and causing trouble with other requests. This all depends on what phase
/// the request is currently in.
///
/// In any case, the goal here is to swap out the user's request buffers
/// and replace them with cancellation buffers which will be transparent
/// to the link as it completes the request.
void
ircd::server::cancel(request &request,
tag &tag)
noexcept
{
// Must have a fully associated request/tag which has committed some
// data to the wire to enter this routine.
assert(tag.committed());
assert(!tag.canceled());
assert(request.tag == &tag);
assert(tag.request == &request);
// Disassociate the user's request and add our dummy request in its place.
disassociate(request, tag);
assert(tag.request == nullptr);
tag.request = new server::request{};
tag.request->tag = &tag;
// Setup the cancellation buffers by mirroring the current state of the
// user's buffers.
const size_t cancellation_size
{
size(request.out) + size(request.in)
};
tag.cancellation = std::make_unique<char[]>(cancellation_size);
char *ptr{tag.cancellation.get()};
const mutable_buffer out_head{ptr, size(request.out.head)};
tag.request->out.head = out_head;
ptr += size(out_head);
const mutable_buffer out_content{ptr, size(request.out.content)};
tag.request->out.content = out_content;
ptr += size(out_content);
const mutable_buffer in_head{ptr, size(request.in.head)};
tag.request->in.head = in_head;
ptr += size(in_head);
const mutable_buffer in_content{ptr, size(request.in.content)};
// The nullity (btw that's a real word) of in.content has to be preserved
// between the user's tag and the cancellation tag. This is important for
// a dynamic chunked encoded response which has null in.content until done.
if(!null(request.in.content))
{
tag.request->in.content = in_content;
ptr += size(in_content);
}
else tag.request->in.content = request.in.content;
assert(size_t(std::distance(tag.cancellation.get(), ptr)) == cancellation_size);
// If the head is not completely written we have to copy the remainder from where
// the socket left off.
if(tag.state.written < size(request.out.head))
{
const const_buffer src
{
data(request.out.head) + tag.state.written, size(request.out.head) - tag.state.written
};
const mutable_buffer dst
{
out_head + tag.state.written
};
copy(dst, src);
}
// If the content is not completely written we have to copy the remainder from where
// the socket left off.
const size_t content_written
{
tag.state.written > size(request.out.head)? tag.state.written - size(request.out.head) : 0
};
if(content_written < size(request.out.content))
{
const const_buffer src
{
data(request.out.content) + content_written, size(request.out.content) - content_written
};
const mutable_buffer dst
{
out_content + content_written
};
copy(dst, src);
}
// If the head is not completely read we have to copy what's been received so far so
// we can parse a coherent head.
if(tag.state.head_read > 0 && tag.state.head_read < size(request.in.head))
{
const const_buffer src
{
data(request.in.head), tag.state.head_read
};
const mutable_buffer dst
{
data(in_head), size(in_head)
};
copy(dst, src);
}
// Normally we have no reason to copy content, but there is one exception:
// If the content is chunked encoding and the tag is in the phase of
// receiving the chunk head we have to copy what's been received of that
// head so far so the grammar can parse a coherent head to continue.
if(tag.state.chunk_length == size_t(-1) && !null(request.in.content))
{
const const_buffer src
{
data(request.in.content) + tag.state.content_length,
tag.state.content_read - tag.state.content_length
};
const mutable_buffer dst
{
in_content + tag.state.content_length
};
copy(dst, src);
}
// Moving the dynamic buffer should have no real effect because the
// cancellation buffer already took over for it. We could do it anyway
// to prevent regressions but at the cost of maintaining twice the memory
// allocated. For now it's commented to let it die with the user's req.
//tag.request->in.dynamic = std::move(request.in.dynamic);
// Moving the chunk vector is important to maintain the state of dynamic
// chunk transfers through this cancel. There is no condition here for if
// this is not a dynamic chunk transfer because it's trivial.
tag.request->in.chunks = std::move(request.in.chunks);
}
void
ircd::server::associate(request &request,
tag &tag)
{
assert(request.tag == nullptr);
assert(tag.request == nullptr);
auto &future
{
static_cast<ctx::future<http::code> &>(request)
};
future = tag.p;
request.tag = &tag;
tag.request = &request;
}
void
ircd::server::associate(request &request,
tag &cur,
tag &&old)
noexcept
{
assert(request.tag == &old); // ctor moved
assert(cur.request == &request); // ctor moved
assert(old.request == &request); // ctor didn't trash old
cur.request = &request;
old.request = nullptr;
request.tag = &cur;
}
void
ircd::server::associate(request &cur,
tag &tag,
request &&old)
noexcept
{
assert(tag.request == &old); // ctor already moved
assert(cur.tag == &tag); // ctor already moved
assert(old.tag == &tag); // ctor didn't trash old
cur.tag = &tag;
tag.request = &cur;
old.tag = nullptr;
}
void
ircd::server::disassociate(request &request,
tag &tag)
{
assert(request.tag == &tag);
assert(tag.request == &request);
assert(tag.abandoned());
request.tag = nullptr;
tag.request = nullptr;
// If the original request was canceled a new request was attached in its
// place in addition to an cancellation buffer. The existence of this
// cancellation buffer indicates that we must delete the request here.
// This is a little hacky but it gets the job done.
if(bool(tag.cancellation))
delete &request;
}
void
ircd::server::tag::wrote_buffer(const const_buffer &buffer)
{
assert(request);
const auto &req{*request};
state.written += size(buffer);
if(state.written <= size(req.out.head))
{
assert(data(buffer) >= begin(req.out.head));
assert(data(buffer) < end(req.out.head));
}
else if(state.written <= size(req.out.head) + size(req.out.content))
{
assert(data(buffer) >= begin(req.out.content));
assert(data(buffer) < end(req.out.content));
assert(state.written <= write_size());
// Invoke the user's optional progress callback; this function
// should be marked noexcept and has no reason to throw yet.
if(req.out.progress)
req.out.progress(buffer, const_buffer{data(req.out.content), state.written});
}
else
{
assert(0);
}
}
ircd::const_buffer
ircd::server::tag::make_write_buffer()
const
{
assert(request);
const auto &req{*request};
return
state.written < size(req.out.head)?
make_write_head_buffer():
state.written < size(req.out.head) + size(req.out.content)?
make_write_content_buffer():
const_buffer{};
}
ircd::const_buffer
ircd::server::tag::make_write_head_buffer()
const
{
assert(request);
const auto &req{*request};
const size_t remain
{
size(req.out.head) - state.written
};
const const_buffer window
{
data(req.out.head) + state.written, remain
};
return window;
}
ircd::const_buffer
ircd::server::tag::make_write_content_buffer()
const
{
assert(request);
const auto &req{*request};
assert(state.written >= size(req.out.head));
const size_t content_offset
{
state.written - size(req.out.head)
};
const size_t remain
{
size(req.out.head) + size(req.out.content) - state.written
};
const const_buffer window
{
data(req.out.content) + content_offset, remain
};
return window;
}
/// Called by the controller of the socket with a view of the data received by
/// the socket. The location and size of `buffer` is the same or smaller than
/// the buffer previously supplied by make_read_buffer().
///
/// Sometimes make_read_buffer() supplies a buffer that is too large, and some
/// data read off the socket does not belong to this tag. In that case, This
/// function returns a const_buffer viewing the portion of `buffer` which is
/// considered the "overrun," and the socket controller will copy that over to
/// the next tag.
///
/// The tag indicates it is entirely finished with receiving its data by
/// setting the value of `done` to true. Otherwise it is assumed false.
///
/// The link argument is not to be used to control/modify the link from the
/// tag; it's only a backreference to flash information to the link/peer
/// through specific callbacks so the peer can learn information.
///
ircd::const_buffer
ircd::server::tag::read_buffer(const const_buffer &buffer,
bool &done,
link &link)
{
assert(request);
if(state.status == (http::code)0)
return read_head(buffer, done, link);
if(state.chunk_length == size_t(-1) && null(request->in.content))
return read_chunk_dynamic_head(buffer, done);
if(state.chunk_length == size_t(-1))
return read_chunk_head(buffer, done);
if(state.chunk_length && null(request->in.content))
return read_chunk_dynamic_content(buffer, done);
if(state.chunk_length)
return read_chunk_content(buffer, done);
return read_content(buffer, done);
}
ircd::const_buffer
ircd::server::tag::read_head(const const_buffer &buffer,
bool &done,
link &link)
{
assert(request);
auto &req{*request};
// informal search for head terminator
static const string_view terminator{"\r\n\r\n"};
const auto pos
{
string_view{buffer}.find(terminator)
};
// No terminator found; account for what was received in this buffer
// for the next call to make_head_buffer() preparing for the subsequent
// invocation of this function with more data.
if(pos == string_view::npos)
{
state.head_read += size(buffer);
return {};
}
// This indicates how much head was just received from this buffer only,
// including the terminator which is considered part of the dome.
const size_t addl_head_bytes
{
pos + size(terminator)
};
// The received buffer may go past the end of the head.
assert(addl_head_bytes <= size(buffer));
const size_t beyond_head_len
{
size(buffer) - addl_head_bytes
};
// The final update for the confirmed length of the head.
state.head_read += addl_head_bytes;
const size_t &head_read{state.head_read};
assert(head_read + beyond_head_len <= size(req.in.head));
// Window on any data in the buffer after the head.
const const_buffer beyond_head
{
data(req.in.head) + head_read, beyond_head_len
};
// Before changing the user's head buffer, we branch for a feature that
// allows the user to receive head and content into a single contiguous
// buffer by assigning in.content = in.head.
const bool contiguous
{
data(req.in.content) == data(req.in.head)
};
// Alternatively branch for a feature that allows dynamic allocation of
// the content buffer if the user did not specify any buffer.
const bool dynamic
{
!contiguous && empty(req.in.content)
};
// Resize the user's head buffer tight to the head; this is how we convey
// the size of the dome back to the user.
state.head_rem = size(req.in.head) - head_read;
req.in.head = mutable_buffer
{
data(req.in.head), head_read
};
// Setup the capstan and mark the end of the tape
parse::buffer pb{req.in.head};
parse::capstan pc{pb};
pc.read += size(req.in.head);
// Play the tape through the formal grammar.
const http::response::head head{pc};
assert(pb.completed() == head_read);
state.status = http::status(head.status);
state.content_length = head.content_length;
// Proffer the HTTP head to the peer instance which owns the link working
// this tag so it can learn from any header data.
assert(link.peer);
link.peer->handle_head_recv(link, *this, head);
if(contiguous)
{
const auto content_max
{
std::max(ssize_t(size(req.in.content) - head_read), ssize_t(0))
};
req.in.content = mutable_buffer
{
data(req.in.head) + head_read, size_t(content_max)
};
}
// Branch for starting chunked encoding. We feed it whatever we have from
// beyond the head as whole or part (or none) of the first chunk. Similar
// to the non-chunked routine below, beyond_head may include all of the
// chunk content and then part of the next message too: read_chunk_head
// will return anything beyond this message as overrun and indicate done.
if(head.transfer_encoding == "chunked")
{
if(dynamic)
{
assert(req.opt);
req.in.chunks.reserve(req.opt->chunks_reserve);
}
const const_buffer chunk
{
!dynamic?
const_buffer{data(req.in.content), move(req.in.content, beyond_head)}:
beyond_head
};
state.chunk_length = -1;
const const_buffer overrun
{
!dynamic?
read_chunk_head(chunk, done):
read_chunk_dynamic_head(chunk, done)
};
assert(empty(overrun) || done == true);
return overrun;
}
// If no branch taken the rest of this function expects a content length
// to be known from the received head.
if(head.transfer_encoding)
throw error
{
"Unsupported transfer-encoding '%s'", head.transfer_encoding
};
if(dynamic)
{
assert(req.opt);
const size_t alloc_size
{
std::min(state.content_length, req.opt->content_length_maxalloc)
};
req.in.dynamic = unique_buffer<mutable_buffer>{alloc_size};
req.in.content = req.in.dynamic;
}
// Now we check how much content was received beyond the head
const size_t &content_read
{
std::min(state.content_length, beyond_head_len)
};
// Now we know how much bleed into the next message was also received
assert(beyond_head_len >= content_read);
const size_t beyond_content_len
{
beyond_head_len - content_read
};
const const_buffer partial_content
{
data(req.in.head) + head_read, content_read
};
// Anything remaining is not our response and must be given back.
const const_buffer overrun
{
data(beyond_head) + size(partial_content), beyond_content_len
};
// Reduce the user's content buffer to the content-length. This is sort of
// how we convey the content-length back to the user. The buffer size will
// eventually reflect how much content was actually received; the user can
// find the given content-length by parsing the header.
req.in.content = mutable_buffer
{
data(req.in.content), std::min(state.content_length, size(req.in.content))
};
// Any partial content was written to the head buffer by accident,
// that may have to be copied over to the content buffer.
if(!empty(partial_content) && !contiguous)
copy(req.in.content, partial_content);
// Invoke the read_content() routine which will increment this->content_read
read_content(partial_content, done);
assert(state.content_read == size(partial_content));
assert(state.content_read == state.content_length || !done);
return overrun;
}
ircd::const_buffer
ircd::server::tag::read_content(const const_buffer &buffer,
bool &done)
{
assert(request);
auto &req{*request};
const auto &content{req.in.content};
// The amount of remaining content for the response sequence
assert(size(content) + content_overflow() >= state.content_read);
assert(size(content) + content_overflow() == state.content_length);
const size_t remaining
{
size(content) + content_overflow() - state.content_read
};
// The amount of content read in this buffer only.
const size_t addl_content_read
{
std::min(size(buffer), remaining)
};
state.content_read += addl_content_read;
assert(size(buffer) - addl_content_read == 0);
assert(state.content_read <= size(content) + content_overflow());
assert(state.content_read <= state.content_length);
// Invoke the user's optional progress callback; this function
// should be marked noexcept for the time being.
if(req.in.progress)
req.in.progress(buffer, const_buffer{data(content), state.content_read});
if(state.content_read == size(content) + content_overflow())
{
assert(state.content_read == state.content_length);
assert(!done);
done = true;
set_value(state.status);
}
return {};
}
ircd::const_buffer
ircd::server::tag::read_chunk_head(const const_buffer &buffer,
bool &done,
const uint8_t recursion_level)
{
assert(request);
auto &req{*request};
const auto &content{req.in.content};
// informal search for head terminator
static const string_view terminator{"\r\n"};
const auto pos
{
string_view{buffer}.find(terminator)
};
if(pos == string_view::npos)
{
state.content_read += size(buffer);
return {};
}
// This indicates how much head was just received from this buffer only.
const size_t addl_head_bytes
{
pos + size(terminator)
};
// The received buffer may go past the end of the head.
assert(addl_head_bytes <= size(buffer));
const size_t beyond_head_length
{
size(buffer) - addl_head_bytes
};
// The total head length is found from the end of the last chunk content
state.content_read += addl_head_bytes;
assert(state.content_read > state.content_length);
const size_t head_length
{
state.content_read - state.content_length
};
// Window on any data in the buffer after the head.
const const_buffer beyond_head
{
data(content) + state.content_length + head_length, beyond_head_length
};
// Setup the capstan and mark the end of the tape
parse::buffer pb
{
mutable_buffer
{
data(content) + state.content_length, head_length
}
};
parse::capstan pc{pb};
pc.read += head_length;
// Play the tape through the formal grammar.
const http::response::chunk chunk{pc};
state.chunk_length = chunk.size + size(terminator);
// Now we check how much chunk was received beyond the head
const auto &chunk_read
{
std::min(state.chunk_length, beyond_head_length)
};
// Now we know how much bleed into the next message was also received
assert(beyond_head_length >= chunk_read);
const size_t beyond_chunk_length
{
beyond_head_length - chunk_read
};
// Finally we erase the chunk head by replacing it with everything received
// after it.
const mutable_buffer target
{
data(content) + state.content_length, beyond_head_length
};
move(target, beyond_head);
// Increment the content_length to now include this chunk
state.content_length += state.chunk_length;
// Adjust the content_read to erase the chunk head.
state.content_read -= head_length;
const const_buffer partial_chunk
{
data(target), chunk_read
};
const const_buffer overrun
{
data(target) + chunk_read, beyond_chunk_length
};
assert(state.chunk_length >= 2);
read_chunk_content(partial_chunk, done);
if(done)
return overrun;
// Prevent stack overflow from lots of tiny chunks nagled together.
if(unlikely(recursion_level >= 32))
throw error
{
"Chunking recursion limit exceeded"
};
return read_chunk_head(overrun, done, recursion_level + 1);
}
ircd::const_buffer
ircd::server::tag::read_chunk_content(const const_buffer &buffer,
bool &done)
{
assert(request);
auto &req{*request};
const auto &content{req.in.content};
// The amount of remaining content for the response sequence
const size_t remaining
{
content_remaining()
};
// The amount of content read in this buffer only.
const size_t addl_content_read
{
std::min(size(buffer), remaining)
};
// Increment the read counters for this chunk and all chunks.
state.chunk_read += addl_content_read;
state.content_read += addl_content_read;
assert(state.chunk_read <= state.content_read);
if(state.content_read == state.content_length)
{
// This branch is taken at the completion of a chunk. The size
// all the buffers is rolled back to hide the terminator so it's
// either ignored or overwritten so it doesn't leak to the user.
static const string_view terminator{"\r\n"};
assert(state.content_length >= size(terminator));
state.content_length -= size(terminator);
state.content_read -= size(terminator);
assert(state.chunk_length >= 2);
assert(state.chunk_read == state.chunk_length);
state.chunk_length -= size(terminator);
state.chunk_read -= size(terminator);
if(state.chunk_length == 0)
{
assert(state.chunk_read == 0);
assert(!done);
done = true;
req.in.content = mutable_buffer{data(req.in.content), state.content_length};
set_value(state.status);
}
}
// Invoke the user's optional progress callback; this function
// should be marked noexcept for the time being.
if(req.in.progress && !done)
req.in.progress(buffer, const_buffer{data(content), state.content_read});
if(state.content_read == state.content_length)
{
assert(state.chunk_read == state.chunk_length);
assert(state.chunk_read <= state.content_read);
state.chunk_length = size_t(-1);
state.chunk_read = 0;
}
return {};
}
ircd::const_buffer
ircd::server::tag::read_chunk_dynamic_head(const const_buffer &buffer,
bool &done,
const uint8_t recursion_level)
{
assert(request);
auto &req{*request};
// informal search for head terminator
static const string_view terminator{"\r\n"};
const auto pos
{
string_view{buffer}.find(terminator)
};
if(pos == string_view::npos)
{
state.chunk_read += size(buffer);
state.content_read += size(buffer);
return {};
}
// This indicates how much head was just received from this buffer only.
const size_t addl_head_bytes
{
pos + size(terminator)
};
// The received buffer may go past the end of the head.
assert(addl_head_bytes <= size(buffer));
const size_t beyond_head_length
{
size(buffer) - addl_head_bytes
};
state.chunk_read += addl_head_bytes;
const auto head_length{state.chunk_read};
state.chunk_read = 0;
// Window on any data in the buffer after the head.
const const_buffer beyond_head
{
data(buffer) + addl_head_bytes, beyond_head_length
};
// Setup the capstan and mark the end of the tape
parse::buffer pb
{
mutable_buffer
{
data(req.in.head) + state.head_read, head_length
}
};
parse::capstan pc{pb};
pc.read += head_length;
// Play the tape through the formal grammar.
const http::response::chunk chunk{pc};
assert(state.chunk_length == size_t(-1));
state.chunk_length = chunk.size + size(terminator);
// Increment the content_length to now include this chunk
state.content_length += state.chunk_length;
// Allocate the chunk content on the vector.
//TODO: maxalloc
req.in.chunks.emplace_back(state.chunk_length);
// Now we check how much chunk was received beyond the head
// state.chunk_head is still 0 here because that's only incremented
// in the content read function.
const auto &chunk_read
{
std::min(state.chunk_length, beyond_head_length)
};
// Now we know how much bleed into the next message was also received
assert(beyond_head_length >= chunk_read);
const size_t beyond_chunk_length
{
beyond_head_length - chunk_read
};
const const_buffer partial_chunk
{
data(beyond_head), chunk_read
};
const size_t copied
{
copy(req.in.chunks.back(), partial_chunk)
};
const const_buffer overrun
{
data(beyond_head) + chunk_read, beyond_chunk_length
};
assert(state.chunk_length >= 2);
read_chunk_dynamic_content(partial_chunk, done);
if(done)
return overrun;
// Prevent stack overflow from lots of tiny chunks nagled together.
if(unlikely(recursion_level >= 32))
throw error
{
"Chunking recursion limit exceeded"
};
return read_chunk_dynamic_head(overrun, done, recursion_level + 1);
}
ircd::const_buffer
ircd::server::tag::read_chunk_dynamic_content(const const_buffer &buffer,
bool &done)
{
assert(request);
auto &req{*request};
assert(state.chunk_length != size_t(-1));
assert(null(req.in.content));
assert(!req.in.chunks.empty());
const auto &chunk
{
req.in.chunks.back()
};
// The amount of remaining content for the response sequence
assert(state.chunk_read <= size(chunk));
const size_t remaining
{
size(chunk) - state.chunk_read
};
// The amount of content read in this buffer only.
const size_t addl_content_read
{
std::min(size(buffer), remaining)
};
// Increment the read counters for this chunk and all chunks.
state.chunk_read += addl_content_read;
state.content_read += addl_content_read;
assert(state.chunk_read <= state.content_read);
if(state.chunk_read == state.chunk_length)
{
static const string_view terminator{"\r\n"};
state.content_length -= size(terminator);
state.content_read -= size(terminator);
assert(state.chunk_length >= 2);
assert(state.chunk_read == state.chunk_length);
state.chunk_length -= size(terminator);
state.chunk_read -= size(terminator);
auto &chunk{req.in.chunks.back()};
std::get<1>(chunk) -= size(terminator);
assert(size(chunk) == state.chunk_length);
assert(std::get<0>(chunk) <= std::get<1>(chunk));
if(state.chunk_length == 0)
{
assert(state.chunk_read == 0);
assert(!done);
done = true;
assert(req.opt);
if(req.opt->contiguous_content)
{
assert(state.content_length == size_chunks(req.in));
assert(req.in.chunks.size() >= 1);
assert(empty(req.in.chunks.back()));
req.in.chunks.pop_back();
if(req.in.chunks.size() > 1)
{
req.in.dynamic = size_chunks(req.in);
req.in.content = req.in.dynamic;
size_t copied{0};
for(const auto &buffer : req.in.chunks)
copied += copy(req.in.content + copied, buffer);
assert(copied == size(req.in.content));
assert(copied == state.content_length);
}
else if(req.in.chunks.size() == 1)
{
req.in.dynamic = std::move(req.in.chunks.front());
req.in.content = req.in.dynamic;
assert(size(req.in.content) == state.content_length);
}
req.in.chunks.clear();
}
set_value(state.status);
}
}
// Invoke the user's optional progress callback; this function
// should be marked noexcept for the time being.
if(req.in.progress && !done)
req.in.progress(buffer, const_buffer{data(chunk), state.chunk_read});
if(state.chunk_read == state.chunk_length)
{
assert(state.chunk_read == state.chunk_length);
assert(state.chunk_read <= state.content_read);
state.chunk_length = size_t(-1);
state.chunk_read = 0;
}
return {};
}
/// An idempotent operation that provides the location of where the socket
/// should place the next received data. The tag figures this out based on
/// whether it receiving HTTP head data or whether it is in content mode.
///
ircd::mutable_buffer
ircd::server::tag::make_read_buffer()
const
{
assert(request);
assert(state.head_read <= size(request->in.head));
assert(state.content_read <= state.content_length);
if(state.status == (http::code)0)
return make_read_head_buffer();
if(state.chunk_length == size_t(-1) && null(request->in.content))
return make_read_chunk_dynamic_head_buffer();
if(state.chunk_length == size_t(-1))
return make_read_chunk_head_buffer();
if(state.chunk_length && null(request->in.content))
return make_read_chunk_dynamic_content_buffer();
if(state.chunk_length)
return make_read_chunk_content_buffer();
if(state.content_read >= size(request->in.content))
return make_read_discard_buffer();
return make_read_content_buffer();
}
ircd::mutable_buffer
ircd::server::tag::make_read_head_buffer()
const
{
assert(request);
const auto &req{*request};
const auto &head{req.in.head};
if(unlikely(size(req.in.head) <= state.head_read))
throw buffer_overrun
{
"Supplied buffer of %zu too small for HTTP head", size(req.in.head)
};
const size_t remaining
{
size(head) - state.head_read
};
const mutable_buffer buffer
{
data(head) + state.head_read, remaining
};
assert(size(buffer) <= size(head));
assert(size(buffer) > 0);
return buffer;
}
ircd::mutable_buffer
ircd::server::tag::make_read_content_buffer()
const
{
assert(request);
const auto &req{*request};
const auto &content{req.in.content};
if(unlikely(size(content) <= state.content_read))
throw buffer_overrun
{
"Content buffer of %zu bytes too small to read %zu bytes of content",
size(content),
state.content_length
};
// The amount of bytes we still have to read to for the response
const size_t remaining
{
size(content) - state.content_read
};
assert(remaining > 0);
return
{
data(content) + state.content_read, remaining
};
}
/// The chunk head buffer starts after the last chunk ended and has a size of
/// the rest of the available content buffer (hopefully much less will be
/// needed). If only part of the chunk head was received previously this
/// function accounts for that by returning a buffer which starts at the
/// content_read offset (which is at the end of that previous read).
///
ircd::mutable_buffer
ircd::server::tag::make_read_chunk_head_buffer()
const
{
assert(request);
assert(state.chunk_length == size_t(-1));
assert(state.content_read >= state.content_length);
const auto &req{*request};
const auto &content{req.in.content};
if(unlikely(size(content) <= state.content_read))
throw buffer_overrun
{
"Content buffer of %zu bytes too small to read next chunk header",
size(content)
};
const size_t remaining
{
size(content) - state.content_read
};
const mutable_buffer buffer
{
data(content) + state.content_read, remaining
};
assert(size(buffer) > 0);
return buffer;
}
ircd::mutable_buffer
ircd::server::tag::make_read_chunk_content_buffer()
const
{
assert(request);
assert(state.chunk_length > 0);
assert(state.content_read <= state.content_length);
const auto &req{*request};
const auto &content{req.in.content};
assert(size(content) >= state.content_read);
const size_t buffer_remaining
{
size(content) - state.content_read
};
const size_t chunk_remaining
{
content_remaining()
};
assert(chunk_remaining <= state.chunk_length);
assert(chunk_remaining == state.content_length - state.content_read);
const size_t buffer_size
{
std::min(buffer_remaining, chunk_remaining)
};
if(unlikely(buffer_size < chunk_remaining))
throw buffer_overrun
{
"Content buffer of %zu bytes too small to read remaining %zu of chunk",
size(content),
chunk_remaining
};
const mutable_buffer buffer
{
data(content) + state.content_read, buffer_size
};
assert(size(buffer) > 0);
return buffer;
}
/// The dynamic chunk head buffer starts after the main head and has a size
/// of the remaining main head buffer. This area is overwritten for each
/// chunk head.
///
ircd::mutable_buffer
ircd::server::tag::make_read_chunk_dynamic_head_buffer()
const
{
assert(request);
const auto &req{*request};
assert(state.chunk_length == size_t(-1));
assert(null(req.in.content));
assert(size(req.in.head) >= state.head_read);
const size_t head_max
{
size(req.in.head) + state.head_rem
};
// The total offset in the head buffer is the message head plus the
// amount of chunk head received so far, which is kept in chunk_read.
const size_t head_offset
{
state.head_read + state.chunk_read
};
assert(head_max >= head_offset);
if(unlikely(head_max - head_offset <= 16))
throw buffer_overrun
{
"Remaining head buffer of %zu bytes too small to read next chunk header",
head_max - state.head_read
};
const size_t remaining
{
head_max - head_offset
};
const mutable_buffer buffer
{
data(req.in.head) + state.head_read + state.chunk_read, remaining
};
assert(size(buffer) > 0);
return buffer;
}
ircd::mutable_buffer
ircd::server::tag::make_read_chunk_dynamic_content_buffer()
const
{
assert(request);
const auto &req{*request};
assert(state.chunk_length > 0);
assert(state.content_read <= state.content_length);
assert(null(req.in.content));
assert(!req.in.chunks.empty());
const auto &buffer
{
req.in.chunks.back()
};
assert(size(buffer) == state.chunk_length);
assert(state.chunk_read <= size(buffer));
const size_t buffer_remaining
{
size(buffer) - state.chunk_read
};
const mutable_buffer ret
{
data(buffer) + state.chunk_read, buffer_remaining
};
assert(size(ret) > 0);
return ret;
}
ircd::mutable_buffer
ircd::server::tag::make_read_discard_buffer()
const
{
assert(request);
assert(content_overflow() > 0);
assert(content_overflow() <= state.content_read);
assert(state.content_read >= size(request->in.content));
const size_t remaining
{
content_overflow() - state.content_read
};
static char buffer[512];
const size_t buffer_max
{
std::min(remaining, sizeof(buffer))
};
return
{
buffer, buffer_max
};
}
size_t
ircd::server::tag::content_remaining()
const
{
assert(state.content_length >= state.content_read);
return state.content_length - state.content_read;
}
size_t
ircd::server::tag::content_overflow()
const
{
assert(request);
const auto &req{*request};
const ssize_t diff(state.content_length - size(req.in.content));
return std::max(diff, ssize_t(0));
}
template<class... args>
void
ircd::server::tag::set_value(args&&... a)
{
if(abandoned())
return;
const http::code &code
{
std::forward<args>(a)...
};
assert(request->opt);
if(request->opt->http_exceptions && code >= http::code(300))
{
const string_view content
{
data(request->in.content), size(request->in.content)
};
set_exception(http::error{code, std::string{content}});
return;
}
p.set_value(code);
}
template<class... args>
void
ircd::server::tag::set_exception(args&&... a)
{
if(abandoned())
return;
set_exception(std::make_exception_ptr(std::forward<args>(a)...));
}
void
ircd::server::tag::set_exception(std::exception_ptr eptr)
{
if(abandoned())
return;
p.set_exception(std::move(eptr));
}
bool
ircd::server::tag::abandoned()
const
{
return !p.valid();
}
bool
ircd::server::tag::canceled()
const
{
return bool(cancellation);
}
bool
ircd::server::tag::committed()
const
{
return write_completed() > 0;
}
size_t
ircd::server::tag::read_remaining()
const
{
return read_size() - read_completed();
}
size_t
ircd::server::tag::read_completed()
const
{
return state.head_read + state.content_read;
}
size_t
ircd::server::tag::read_size()
const
{
return state.head_read + state.content_length;
}
size_t
ircd::server::tag::write_remaining()
const
{
return write_size() - write_completed();
}
size_t
ircd::server::tag::write_completed()
const
{
return state.written;
}
size_t
ircd::server::tag::write_size()
const
{
return request? size(request->out) : 0;
}