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construct/ircd/net_dns_resolver.cc
2022-06-29 14:42:42 -07:00

1018 lines
18 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.
decltype(ircd::net::dns::resolver_instance)
ircd::net::dns::resolver_instance;
decltype(ircd::net::dns::resolver::timeout)
ircd::net::dns::resolver::timeout
{
{ "name", "ircd.net.dns.resolver.timeout" },
{ "default", 5000L },
};
decltype(ircd::net::dns::resolver::send_rate)
ircd::net::dns::resolver::send_rate
{
{ "name", "ircd.net.dns.resolver.send_rate" },
{ "default", 200L },
};
decltype(ircd::net::dns::resolver::send_burst)
ircd::net::dns::resolver::send_burst
{
{ "name", "ircd.net.dns.resolver.send_burst" },
{ "default", 4L },
};
decltype(ircd::net::dns::resolver::retry_max)
ircd::net::dns::resolver::retry_max
{
{ "name", "ircd.net.dns.resolver.retry_max" },
{ "default", 20L },
};
decltype(ircd::net::dns::resolver::servers)
ircd::net::dns::resolver::servers
{
{
{ "name", "ircd.net.dns.resolver.servers" },
{ "default", "4.2.2.1 4.2.2.2 4.2.2.3 4.2.2.4 4.2.2.5 4.2.2.6" },
}, []
{
if(bool(ircd::net::dns::resolver_instance))
ircd::net::dns::resolver_instance->set_servers();
}
};
//
// interface
//
uint16_t
ircd::net::dns::resolver_call(const hostport &hp,
const opts &opts)
{
if(unlikely(!resolver_instance))
throw error
{
"Cannot resolve '%s': resolver unavailable.",
host(hp)
};
auto &resolver
{
*dns::resolver_instance
};
if(unlikely(!resolver.ns.is_open()))
throw error
{
"Cannot resolve '%s': resolver is closed.",
host(hp)
};
return resolver(hp, opts);
}
//
// resolver::resolver
//
ircd::net::dns::resolver::resolver(answers_callback callback)
:callback
{
std::move(callback)
}
,ns
{
ios::get()
}
,recv_context
{
"net.dns.R",
768_KiB,
std::bind(&resolver::recv_worker, this),
context::POST
}
,timeout_context
{
"net.dns.T",
512_KiB,
std::bind(&resolver::timeout_worker, this),
context::POST
}
,sendq_context
{
"net.dns.S",
256_KiB,
std::bind(&resolver::sendq_worker, this),
context::POST
}
{
ns.open(ip::udp::v4());
ns.non_blocking(true);
set_servers();
}
ircd::net::dns::resolver::~resolver()
noexcept
{
const ctx::uninterruptible::nothrow ui;
done.wait([this]() noexcept
{
if(!tags.empty())
log::warning
{
log, "Waiting for %zu unfinished DNS resolutions...",
tags.size()
};
return tags.empty();
});
ns.close();
assert(!mutex.locked());
assert(sendq.empty());
assert(tags.empty());
}
/// Internal resolver entry interface.
uint16_t
ircd::net::dns::resolver::operator()(const hostport &hp,
const opts &opts)
{
const ctx::critical_assertion ca;
auto &tag(set_tag(hp, opts)); try
{
tag.question = make_query(tag.qbuf, tag);
submit(tag);
}
catch(...)
{
remove(tag);
throw;
}
return tag.id;
}
ircd::const_buffer
ircd::net::dns::resolver::make_query(const mutable_buffer &buf,
tag &tag)
{
thread_local char hostbuf[rfc1035::NAME_BUFSIZE * 2];
string_view hoststr;
switch(tag.opts.qtype)
{
case 0: throw error
{
"Query type is required to form a question."
};
case 33: // SRV
hoststr = make_SRV_key(hostbuf, tag.hp, tag.opts);
break;
default:
hoststr = tolower(hostbuf, host(tag.hp));
break;
}
assert(hoststr);
assert(tag.opts.qtype);
const rfc1035::question question
{
hoststr, tag.opts.qtype
};
return rfc1035::make_query(buf, tag.id, question);
}
template<class... A>
ircd::net::dns::tag &
ircd::net::dns::resolver::set_tag(A&&... args)
{
while(tags.size() < 65535)
{
auto id
{
ircd::rand::integer(1, 65535)
};
auto it{tags.lower_bound(id)};
if(it != end(tags) && it->first == id)
continue;
it = tags.emplace_hint(it,
std::piecewise_construct,
std::forward_as_tuple(id),
std::forward_as_tuple(std::forward<A>(args)...));
it->second.id = id;
return it->second;
}
throw panic
{
"Too many DNS queries"
};
}
void
__attribute__((noreturn))
ircd::net::dns::resolver::sendq_worker()
{
while(1)
{
dock.wait([this]() noexcept
{
assert(sendq.empty() || !tags.empty());
return !sendq.empty() && !server.empty();
});
if(tags.size() > size_t(send_burst))
ctx::sleep(milliseconds(send_rate));
sendq_work();
}
}
void
ircd::net::dns::resolver::sendq_work()
{
const std::lock_guard lock
{
mutex
};
if(unlikely(sendq.empty()))
return;
assert(sendq.size() < 65535);
assert(sendq.size() <= tags.size());
const uint16_t next(sendq.front());
sendq.pop_front();
flush(next);
}
void
ircd::net::dns::resolver::flush(const uint16_t &next)
try
{
auto &tag
{
tags.at(next)
};
submit(tag);
}
catch(const std::out_of_range &e)
{
log::error
{
log, "Queued tag id[%u] is no longer mapped", next
};
}
void
ircd::net::dns::resolver::timeout_worker()
{
while(1)
{
// Dock here until somebody submits a request into the tag map. Also
// wait until recv_idle is asserted which indicates the UDP queue has
// been exhausted.
dock.wait([this]() noexcept
{
return !tags.empty() && recv_idle;
});
check_timeouts(milliseconds(timeout));
}
}
void
ircd::net::dns::resolver::check_timeouts(const milliseconds &timeout)
{
const auto cutoff
{
now<steady_point>() - timeout
};
std::unique_lock lock
{
mutex
};
auto it(begin(tags));
for(; it != end(tags); ++it)
{
auto &tag(it->second);
const auto &id(it->first);
if(check_timeout(id, tag, cutoff))
{
it = tags.erase(it);
return;
}
}
lock.unlock();
ctx::sleep(1800ms);
}
bool
ircd::net::dns::resolver::check_timeout(const uint16_t &id,
tag &tag,
const steady_point &cutoff)
{
if(tag.last == steady_point::min())
return false;
if(tag.last > cutoff)
return false;
log::warning
{
log, "DNS timeout id:%u on attempt %u of %u '%s'",
id,
tag.tries,
size_t(retry_max),
host(tag.hp)
};
if(tag.tries < size_t(retry_max))
{
submit(tag);
return false;
}
static const std::system_error ec
{
make_error_code(std::errc::timed_out)
};
error_one(tag, ec, false);
return true;
}
//
// submit
//
void
ircd::net::dns::resolver::submit(tag &tag)
{
if(!ns.is_open() || server.empty())
{
log::warning
{
log, "dns tag:%u submit queued because no nameserver is available.",
tag.id
};
queue_query(tag);
return;
}
assert(!server.empty());
const auto rate(milliseconds(send_rate) / server.size());
const auto elapsed(now<steady_point>() - send_last);
if(elapsed >= rate || tags.size() <= size_t(send_burst))
send_query(tag);
else
queue_query(tag);
dock.notify_all();
}
void
ircd::net::dns::resolver::send_query(tag &tag)
try
{
assert(!server.empty());
++server_next %= server.size();
const auto &ep
{
server.at(server_next)
};
send_query(ep, tag);
#ifdef RB_DEBUG
char buf[128];
log::debug
{
log, "send tag:%u qtype:%u t:%u `%s' to %s",
tag.id,
tag.opts.qtype,
tag.tries,
host(tag.hp),
string(buf, make_ipport(ep)),
};
#endif
}
catch(const std::out_of_range &)
{
throw error
{
"No DNS servers available for query"
};
}
void
ircd::net::dns::resolver::queue_query(tag &tag)
{
assert(sendq.size() <= tags.size());
if(std::find(begin(sendq), end(sendq), tag.id) != end(sendq))
return;
tag.last = steady_point::min(); // tag to be ignored by the timeout worker
sendq.emplace_back(tag.id);
log::debug
{
log, "queu tag:%u qtype:%u t:%u (tags:%zu sendq:%zu)",
tag.id,
tag.opts.qtype,
tag.tries,
tags.size(),
sendq.size()
};
}
void
ircd::net::dns::resolver::send_query(const ip::udp::endpoint &ep,
tag &tag)
try
{
assert(ns.is_open());
assert(ns.non_blocking());
assert(!empty(tag.question));
const ctx::uninterruptible::nothrow ui;
const const_buffer &buf{tag.question};
const auto sent
{
ns.send_to(asio::const_buffers_1(buf), ep)
};
send_last = now<steady_point>();
tag.last = send_last;
tag.server = make_ipport(ep);
tag.tries++;
}
catch(const std::exception &e)
{
char buf[128];
log::error
{
log, "send tag:%u qtype:%u t:%u `%s' to %s :%s",
tag.id,
tag.opts.qtype,
tag.tries,
host(tag.hp),
string(buf, make_ipport(ep)),
e.what(),
};
throw;
}
//
// recv
//
void
ircd::net::dns::resolver::recv_worker()
try
{
const unique_buffer<mutable_buffer> buf
{
64_KiB
};
while(ns.is_open()) try
{
const auto &[from, reply]
{
recv_recv(buf)
};
handle(from, reply);
}
catch(const boost::system::system_error &e)
{
switch(make_error_code(e).value())
{
case int(std::errc::operation_canceled):
break;
default:
throw;
}
}
}
catch(const std::exception &e)
{
log::critical
{
log, "%s", e.what()
};
}
std::tuple<ircd::net::ipport, ircd::mutable_buffer>
ircd::net::dns::resolver::recv_recv(const mutable_buffer &buf)
{
static const ip::udp::socket::message_flags flags
{
0
};
const asio::mutable_buffers_1 bufs
{
buf
};
// First try a non-blocking receive to find and return anything in the
// queue. If this comes back as -EAGAIN we'll assert recv_idle and then
// conduct the normal blocking receive.
boost::system::error_code ec;
ip::udp::endpoint ep;
size_t recv
{
ns.receive_from(bufs, ep, flags, ec)
};
assert(!ec || recv == 0);
assert(!ec || ec == boost::system::errc::resource_unavailable_try_again);
// branch on any ec, not just -EAGAIN; this time it can throw...
if(likely(ec))
{
const scope_restore recv_idle
{
this->recv_idle, true
};
const auto interruption
{
std::bind(&resolver::handle_interrupt, this, ph::_1)
};
continuation
{
continuation::asio_predicate, interruption, [this, &bufs, &recv, &ep]
(auto &yield)
{
recv = ns.async_receive_from(bufs, ep, yield);
}
};
}
return
{
make_ipport(ep), mutable_buffer
{
data(buf), recv
}
};
}
void
ircd::net::dns::resolver::handle_interrupt(ctx::ctx *const &interruptor)
noexcept
{
if(!ns.is_open())
ns.cancel();
}
void
ircd::net::dns::resolver::handle(const ipport &from,
const mutable_buffer &buf)
try
{
if(unlikely(size(buf) < sizeof(rfc1035::header)))
throw rfc1035::error
{
"Got back %zu bytes < rfc1035 %zu byte header",
size(buf),
sizeof(rfc1035::header)
};
rfc1035::header &header
{
*reinterpret_cast<rfc1035::header *>(data(buf))
};
header.qdcount = ntoh(header.qdcount);
header.ancount = ntoh(header.ancount);
header.nscount = ntoh(header.nscount);
header.arcount = ntoh(header.arcount);
const const_buffer body
{
data(buf) + sizeof(header), size(buf) - sizeof(header)
};
handle_reply(from, header, body);
}
catch(const std::exception &e)
{
log::error
{
log, "%s", e.what()
};
}
void
ircd::net::dns::resolver::handle_reply(const ipport &from,
const header &header,
const const_buffer &body)
{
// The primary mutex is locked here while this result is
// processed. This locks out the sendq and timeout worker.
const std::lock_guard lock
{
mutex
};
const auto it
{
tags.find(header.id)
};
char strbuf[2][128];
if(it == end(tags))
throw error
{
"DNS reply from %s for unrecognized tag id:%u",
string(strbuf[0], from),
header.id
};
auto &tag{it->second};
if(from != tag.server)
throw error
{
"DNS reply from %s for tag:%u which we sent to %s",
string(strbuf[0], from),
header.id,
string(strbuf[1], tag.server)
};
log::debug
{
log, "recv tag:%u qtype:%u t:%u from %s in %s qd:%u an:%u ns:%u ar:%u",
tag.id,
tag.opts.qtype,
tag.tries,
string(strbuf[0], from),
pretty(strbuf[1], nanoseconds(now<steady_point>() - tag.last), 1),
header.qdcount,
header.ancount,
header.nscount,
header.arcount,
};
// Handle ServFail as a special case here. We can try again without
// handling this tag or propagating this error any further yet.
if(header.rcode == 2 && tag.tries < size_t(server.size()))
{
log::error
{
log, "recv tag:%u qtype:%u t:%u from %s protocol error #%u :%s",
tag.id,
tag.opts.qtype,
tag.tries,
string(strbuf[0], from),
header.rcode,
rfc1035::rcode.at(header.rcode)
};
assert(tag.tries > 0);
submit(tag);
return;
}
// The tag is committed to being handled after this point; it will be
// removed from the tags map...
const ctx::uninterruptible::nothrow ui;
const unwind untag{[this, &tag, &it]
{
remove(tag, it);
}};
assert(tag.tries > 0);
tag.last = steady_point::min(); // tag ignored by the timeout worker during handling.
tag.rcode = header.rcode;
handle_reply(header, body, tag);
}
void
ircd::net::dns::resolver::handle_reply(const header &header,
const const_buffer &body,
tag &tag)
try
{
if(unlikely(header.qr != 1))
throw rfc1035::error
{
"Response header is marked as 'Query' and not 'Response'"
};
if(header.qdcount > MAX_COUNT || header.ancount > MAX_COUNT)
throw error
{
"Response contains too many sections..."
};
if(header.qdcount < 1)
throw error
{
"Response does not contain the question."
};
if(!handle_error(header, tag))
throw rfc1035::error
{
"protocol #%u :%s",
header.rcode,
rfc1035::rcode.at(header.rcode)
};
const_buffer buffer
{
body
};
// Questions are regurgitated back to us so they must be parsed first
thread_local std::array<rfc1035::question, MAX_COUNT> qd;
for(size_t i(0); i < header.qdcount; ++i)
consume(buffer, size(qd.at(i).parse(buffer)));
// Answers are parsed into this buffer
thread_local std::array<rfc1035::answer, MAX_COUNT> an;
for(size_t i(0); i < header.ancount; ++i)
consume(buffer, size(an.at(i).parse(buffer)));
const vector_view<const rfc1035::answer> answers
{
an.data(), header.ancount
};
callback({}, tag, answers);
}
catch(const std::exception &e)
{
// There's no need to flash red to the log for NXDOMAIN which is
// common in this system when probing SRV.
const auto level
{
header.rcode != 3? log::ERROR : log::DERROR
};
log::logf
{
log, level, "resolver tag:%u: %s",
tag.id,
e.what()
};
const auto eptr(std::current_exception());
const ctx::exception_handler eh;
callback(eptr, tag, answers{});
}
bool
ircd::net::dns::resolver::handle_error(const header &header,
tag &tag)
{
switch(header.rcode)
{
case 0: // NoError; continue
return true;
case 3: // NXDomain; exception
if(!tag.opts.nxdomain_exceptions)
return true;
return false;
default: // Unhandled error; exception
return false;
}
}
//
// removal
//
// This whole stack must be called under lock
//
void
ircd::net::dns::resolver::cancel_all(const bool &remove)
{
static const std::error_code &ec
{
make_error_code(std::errc::operation_canceled)
};
error_all(ec, remove);
}
void
ircd::net::dns::resolver::error_all(const std::error_code &ec,
const bool &remove)
{
if(tags.empty())
return;
log::dwarning
{
log, "Attempting to cancel all %zu pending tags.", tags.size()
};
const auto eptr
{
make_system_eptr(ec)
};
for(auto &p : tags)
error_one(p.second, eptr, false);
if(remove)
for(auto it(begin(tags)); it != end(tags); it = this->remove(it->second, it));
}
void
ircd::net::dns::resolver::error_one(tag &tag,
const std::system_error &se,
const bool &remove)
{
error_one(tag, std::make_exception_ptr(se), remove);
}
void
ircd::net::dns::resolver::error_one(tag &tag,
const std::exception_ptr &eptr,
const bool &remove)
{
log::error
{
log, "DNS error id:%u :%s",
tag.id,
what(eptr)
};
// value causes tag to be ignored by the timeout worker
tag.last = steady_point::min();
static const answers empty;
callback(eptr, tag, empty);
if(remove)
this->remove(tag);
}
void
ircd::net::dns::resolver::remove(tag &tag)
{
remove(tag, tags.find(tag.id));
}
decltype(ircd::net::dns::resolver::tags)::iterator
ircd::net::dns::resolver::remove(tag &tag,
const decltype(tags)::iterator &it)
{
log::debug
{
log, "fini tag:%u qtype:%u t:%u (tags:%zu sendq:%zu)",
tag.id,
tag.opts.qtype,
tag.tries,
tags.size(),
sendq.size()
};
if(it != end(tags))
unqueue(tag);
const auto ret
{
it != end(tags)?
tags.erase(it):
it
};
if(ret != end(tags))
done.notify_all();
return it;
}
void
ircd::net::dns::resolver::unqueue(tag &tag)
{
const auto it
{
std::find(begin(sendq), end(sendq), tag.id)
};
if(it != end(sendq))
sendq.erase(it);
}
//
// util
//
void
ircd::net::dns::resolver::set_servers()
try
{
const std::string &list(resolver::servers);
set_servers(list);
dock.notify_all();
}
catch(const std::exception &e)
{
log::error
{
log, "Erroneous configuration; falling back to defaults :%s",
e.what()
};
resolver::servers.fault();
if(!ircd::net::dns::resolver_instance)
set_servers();
}
void
ircd::net::dns::resolver::set_servers(const string_view &list)
{
server.clear();
server_next = 0;
tokens(list, ' ', [this]
(const string_view &hp)
{
add_server(hp);
});
if(!empty(list) && server.empty())
throw error
{
"Failed to set any valid DNS servers from a non-empty list."
};
}
void
ircd::net::dns::resolver::add_server(const string_view &str)
try
{
const hostport hp
{
str
};
const auto &port
{
net::port(hp)?
net::port(hp):
uint16_t(53)
};
const ipport ipp
{
host(hp), port
};
add_server(ipp);
}
catch(const std::exception &e)
{
log::error
{
log, "Failed to add server '%s' :%s",
str,
e.what()
};
}
void
ircd::net::dns::resolver::add_server(const ipport &ipp)
{
server.emplace_back(make_endpoint_udp(ipp));
log::debug
{
log, "Adding [%s] as DNS server #%zu",
string(ipp),
server.size()
};
}