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construct/matrix/vm_eval.cc
Jason Volk 987a3eeb6b ircd:Ⓜ️:vm::eval: Add pointer to parent eval; related utils.
ircd:Ⓜ️:vm::eval: Add pointer to child evals; maintain stack.
2020-05-12 22:27:53 -07:00

525 lines
9.6 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.
//
// Eval
//
// Processes any event from any place from any time and does whatever is
// necessary to validate, reject, learn from new information, ignore old
// information and advance the state of IRCd as best as possible.
/// Instance list linkage for all of the evaluations.
template<>
decltype(ircd::util::instance_list<ircd::m::vm::eval>::allocator)
ircd::util::instance_list<ircd::m::vm::eval>::allocator
{};
template<>
decltype(ircd::util::instance_list<ircd::m::vm::eval>::list)
ircd::util::instance_list<ircd::m::vm::eval>::list
{
allocator
};
decltype(ircd::m::vm::eval::id_ctr)
ircd::m::vm::eval::id_ctr;
decltype(ircd::m::vm::eval::executing)
ircd::m::vm::eval::executing;
decltype(ircd::m::vm::eval::injecting)
ircd::m::vm::eval::injecting;
void
ircd::m::vm::eval::seqsort()
{
eval::list.sort([]
(const auto *const &a, const auto *const &b)
{
if(sequence::get(*a) == 0)
return false;
if(sequence::get(*b) == 0)
return true;
return sequence::get(*a) < sequence::get(*b);
});
}
ircd::m::vm::eval *
ircd::m::vm::eval::seqmin()
{
const auto it
{
std::min_element(begin(eval::list), end(eval::list), []
(const auto *const &a, const auto *const &b)
{
if(sequence::get(*a) == 0)
return false;
if(sequence::get(*b) == 0)
return true;
return sequence::get(*a) < sequence::get(*b);
})
};
if(it == end(eval::list))
return nullptr;
if(sequence::get(**it) == 0)
return nullptr;
return *it;
}
ircd::m::vm::eval *
ircd::m::vm::eval::seqmax()
{
const auto it
{
std::max_element(begin(eval::list), end(eval::list), []
(const auto *const &a, const auto *const &b)
{
return sequence::get(*a) < sequence::get(*b);
})
};
if(it == end(eval::list))
return nullptr;
if(sequence::get(**it) == 0)
return nullptr;
return *it;
}
ircd::m::vm::eval *
ircd::m::vm::eval::seqnext(const uint64_t &seq)
{
eval *ret{nullptr};
for(auto *const &eval : eval::list)
{
if(sequence::get(*eval) <= seq)
continue;
if(!ret || sequence::get(*eval) < sequence::get(*ret))
ret = eval;
}
assert(!ret || sequence::get(*ret) > seq);
return ret;
}
bool
ircd::m::vm::eval::sequnique(const uint64_t &seq)
{
return 1 == std::count_if(begin(eval::list), end(eval::list), [&seq]
(const auto *const &eval)
{
return sequence::get(*eval) == seq;
});
}
ircd::m::vm::eval &
ircd::m::vm::eval::get(const event::id &event_id)
{
auto *const ret
{
find(event_id)
};
if(unlikely(!ret))
throw std::out_of_range
{
"eval::get(): event_id not being evaluated."
};
return *ret;
}
ircd::m::vm::eval *
ircd::m::vm::eval::find(const event::id &event_id)
{
eval *ret{nullptr};
for_each([&event_id, &ret](eval &e)
{
if(e.event_)
{
if(e.event_->event_id == event_id)
ret = &e;
}
else if(e.issue)
{
if(e.issue->has("event_id"))
if(string_view{e.issue->at("event_id")} == event_id)
ret = &e;
}
else if(e.event_id == event_id)
ret = &e;
return ret == nullptr;
});
return ret;
}
size_t
ircd::m::vm::eval::count(const event::id &event_id)
{
size_t ret(0);
for_each([&event_id, &ret](eval &e)
{
if(e.event_)
{
if(e.event_->event_id == event_id)
++ret;
}
else if(e.issue)
{
if(e.issue->has("event_id"))
if(string_view{e.issue->at("event_id")} == event_id)
++ret;
}
else if(e.event_id == event_id)
++ret;
return true;
});
return ret;
}
const ircd::m::event *
ircd::m::vm::eval::find_pdu(const event::id &event_id)
{
const m::event *ret{nullptr};
for_each_pdu([&ret, &event_id]
(const m::event &event)
{
if(event.event_id != event_id)
return true;
ret = std::addressof(event);
return false;
});
return ret;
}
const ircd::m::event *
ircd::m::vm::eval::find_pdu(const eval &eval,
const event::id &event_id)
{
const m::event *ret{nullptr};
for(const auto &event : eval.pdus)
{
if(event.event_id != event_id)
continue;
ret = std::addressof(event);
break;
}
return ret;
}
bool
ircd::m::vm::eval::for_each_pdu(const std::function<bool (const event &)> &closure)
{
return for_each([&closure](eval &e)
{
if(!empty(e.pdus))
{
for(const auto &pdu : e.pdus)
if(!closure(pdu))
return false;
}
else if(e.event_)
{
if(!closure(*e.event_))
return false;
}
return true;
});
}
bool
ircd::m::vm::eval::for_each(const std::function<bool (eval &)> &closure)
{
for(eval *const &eval : eval::list)
if(!closure(*eval))
return false;
return true;
}
size_t
ircd::m::vm::eval::count(const ctx::ctx *const &c)
{
return std::count_if(begin(eval::list), end(eval::list), [&c]
(const eval *const &eval)
{
return eval->ctx == c;
});
}
ircd::m::vm::eval *
ircd::m::vm::eval::find_root(const eval &a,
const ctx::ctx &c)
{
eval *ret {nullptr}, *parent {nullptr}; do
{
if(!(parent = find_parent(a, c)))
return ret;
ret = parent;
}
while(1);
}
ircd::m::vm::eval *
ircd::m::vm::eval::find_parent(const eval &a,
const ctx::ctx &c)
{
eval *ret {nullptr};
for_each(&c, [&ret, &a]
(eval &eval)
{
const bool cond
{
(&eval != &a) && (!ret || eval.id > ret->id)
};
ret = cond? &eval : ret;
return true;
});
return ret;
}
bool
ircd::m::vm::eval::for_each(const ctx::ctx *const &c,
const std::function<bool (eval &)> &closure)
{
for(eval *const &eval : eval::list)
if(eval->ctx == c)
if(!closure(*eval))
return false;
return true;
}
//
// eval::eval
//
ircd::m::vm::eval::eval(const vm::opts &opts)
:opts{&opts}
,parent
{
find_parent(*this)
}
{
if(parent)
{
assert(!parent->child);
parent->child = this;
}
}
ircd::m::vm::eval::eval(const vm::copts &opts)
:opts{&opts}
,copts{&opts}
,parent
{
find_parent(*this)
}
{
if(parent)
{
assert(!parent->child);
parent->child = this;
}
}
ircd::m::vm::eval::eval(json::iov &event,
const json::iov &content,
const vm::copts &opts)
:eval{opts}
{
operator()(event, content);
}
ircd::m::vm::eval::eval(const event &event,
const vm::opts &opts)
:eval{opts}
{
operator()(event);
}
ircd::m::vm::eval::eval(const json::array &pdus,
const vm::opts &opts)
:eval{opts}
{
// Sort the events first to avoid complicating the evals; the events might
// be from different rooms but it doesn't matter.
std::vector<m::event> events(begin(pdus), end(pdus));
std::sort(begin(events), end(events));
operator()(events);
}
ircd::m::vm::eval::eval(const vector_view<m::event> &events,
const vm::opts &opts)
:eval{opts}
{
operator()(events);
}
ircd::m::vm::eval::~eval()
noexcept
{
assert(!child);
if(parent)
{
assert(parent->child == this);
parent->child = nullptr;
}
}
size_t
ircd::m::vm::eval::operator()(const vector_view<m::event> &events)
{
assert(opts);
const scope_restore eval_pdus
{
this->pdus, events
};
if(likely(opts->phase[phase::VERIFY] && opts->mfetch_keys))
mfetch_keys();
// Conduct each eval without letting any one exception ruin things for the
// others, including an interrupt. The only exception is a termination.
size_t ret(0);
for(auto it(begin(events)); it != end(events); ++it) try
{
const m::event &event
{
*it
};
const auto status
{
operator()(event)
};
ret += status == fault::ACCEPT;
}
catch(const ctx::interrupted &e)
{
throw;
}
catch(const std::exception &e)
{
continue;
}
return ret;
}
/// Inject a new event originating from this server.
///
ircd::m::vm::fault
ircd::m::vm::eval::operator()(json::iov &event,
const json::iov &contents)
{
return vm::inject(*this, event, contents);
}
ircd::m::vm::fault
ircd::m::vm::eval::operator()(const event &event)
{
return vm::execute(*this, event);
}
ircd::m::vm::eval::operator
const event::id::buf &()
const
{
return event_id;
}
void
ircd::m::vm::eval::mfetch_keys()
const
{
using m::fed::key::server_key;
// Determine federation keys which we don't have.
std::set<server_key> miss;
for(const auto &event : this->pdus)
{
// When the node_id is set (eval on behalf of remote) we only parallel
// fetch keys from that node for events from that node. This is to
// prevent amplification. Note that these will still be evaluated and
// key fetching may be attempted, but not here.
assert(opts);
const auto &origin(json::get<"origin"_>(event));
if(opts->node_id && opts->node_id != origin)
continue;
const json::object &signature
{
json::get<"signatures"_>(event).get(origin)
};
for(const auto &[key_id, sig] : signature)
{
const server_key key(origin, key_id);
const auto it(miss.lower_bound(key));
if(it != end(miss) && *it == key)
continue;
if(m::keys::cache::has(origin, key_id))
continue;
miss.emplace_hint(it, key);
}
}
//TODO: XXX
const std::vector<server_key> queries(begin(miss), end(miss));
if(!queries.empty())
log::debug
{
log, "%s fetching %zu new keys from %zu events...",
loghead(*this),
queries.size(),
this->pdus.size(),
};
const size_t fetched
{
!queries.empty()?
m::keys::fetch(queries):
0UL
};
if(fetched)
log::info
{
log, "%s fetched %zu of %zu new keys from %zu events",
loghead(*this),
fetched,
queries.size(),
this->pdus.size(),
};
}