// The Construct // // Copyright (C) The Construct Developers, Authors & Contributors // Copyright (C) 2016-2020 Jason Volk // // 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::m::acquire::log) ircd::m::acquire::log { "m.acquire" }; template<> decltype(ircd::util::instance_list::allocator) ircd::util::instance_list::allocator {}; template<> decltype(ircd::util::instance_list::list) ircd::util::instance_list::list { allocator }; ircd::m::acquire::acquire::acquire(const struct opts &opts) :opts{opts} ,head_vmopts{opts.vmopts} ,history_vmopts{opts.vmopts} ,state_vmopts{opts.vmopts} { if(opts.head) { head_vmopts.notify_servers = false; head_vmopts.phase.set(m::vm::phase::NOTIFY, false); head_vmopts.phase.set(m::vm::phase::FETCH_PREV, false); head_vmopts.phase.set(m::vm::phase::FETCH_STATE, false); } if(opts.state) { state_vmopts.notify_servers = false; state_vmopts.phase.set(m::vm::phase::FETCH_PREV, false); state_vmopts.phase.set(m::vm::phase::FETCH_STATE, false); state_vmopts.wopts.appendix.set(dbs::appendix::ROOM_HEAD, false); } if(opts.history || opts.timeline) { history_vmopts.notify_servers = false; history_vmopts.phase.set(m::vm::phase::NOTIFY, false); history_vmopts.phase.set(m::vm::phase::FETCH_PREV, false); history_vmopts.phase.set(m::vm::phase::FETCH_STATE, false); history_vmopts.wopts.appendix.set(dbs::appendix::ROOM_HEAD, false); } // Branch to acquire head if(opts.head) if(!opts.depth.second) acquire_head(); // Branch to acquire history if(opts.history) acquire_history(); // Branch to acquire timeline if(opts.timeline) acquire_timeline(); // Branch to acquire state if(opts.state) acquire_state(); } ircd::m::acquire::~acquire() noexcept try { // Complete all work before returning, otherwise everything // will be cancelled on unwind. while(!fetching.empty()) while(handle()); } catch(const ctx::interrupted &) { return; } catch(const ctx::terminated &) { return; } void ircd::m::acquire::acquire_history() { event::idx ref_min { opts.ref.first }; for(size_t i(0); i < opts.rounds; ++i) { if(!fetch_history(ref_min)) break; if(ref_min > opts.ref.second) break; } } bool ircd::m::acquire::fetch_history(event::idx &ref_min) { const auto top { m::top(opts.room.room_id) }; const auto &[top_id, top_depth, top_idx] { top }; auto depth_range { opts.depth }; if(!depth_range.first && opts.viewport_size) depth_range = { m::viewport(opts.room).first, depth_range.second }; if(!depth_range.second) depth_range.second = top_depth; if(size_t(depth_range.second - depth_range.first) < opts.viewport_size) depth_range.first -= std::min(long(opts.viewport_size), depth_range.first); m::room::events::missing missing { opts.room }; bool ret(false); event::idx ref_top(ref_min); missing.for_each(depth_range, [this, &top, &ref_min, &ref_top, &ret] (const event::id &event_id, const int64_t &ref_depth, const event::idx &ref_idx) { if(ctx::interruption_requested()) return false; if(ref_idx < opts.ref.first || ref_idx < ref_min) return true; if(ref_idx > opts.ref.second) return true; // Branch if we have to measure the viewportion if(opts.viewport_size) { const m::event::idx_range idx_range { std::min(ref_idx, std::get(top)), std::max(ref_idx, std::get(top)), }; // Bail if this event sits above the viewport. if(m::room::events::count(opts.room, idx_range) > opts.viewport_size) return true; } const auto ref_id { m::event_id(ref_idx) }; const m::room ref_room { opts.room.room_id, ref_id }; const auto &[sound_depth, sound_idx] { m::sounding(ref_room) }; const auto &[twain_depth, _twain_idx] { sound_idx == ref_idx? m::twain(ref_room): std::make_pair(0L, 0UL) }; const auto gap { sound_depth >= twain_depth? size_t(sound_depth - twain_depth): 0UL }; // Ignore if this ref borders on a gap which does not satisfy the options if(gap < opts.gap.first || gap > opts.gap.second) return true; // The depth on each side of a gap is used as a poor heuristic to // guesstimate how many events might be missing and how much to // request from a remote at once. Due to protocol limitations, this // can err in both directions: // - It lowballs in situations like #ping:maunium.net where the DAG // is wide, causing more rounds of requests to fill a gap. // - It's overzealous in cases of secondary/distant references that // have nothing to do with a gap preceding the ref. // // Fortunately in practice the majority of estimates are close enough. // XXX /get_missing_events should be considered if there's low // confidence in a gap estimate. const auto &limit { std::clamp(gap, 1UL, 48UL) }; const bool submitted { submit(event_id, opts.hint, false, limit, &history_vmopts) }; if(submitted) log::debug { log, "Fetch %s miss prev of %s @%lu in %s @%lu sound:%lu twain:%ld fetching:%zu", string_view{event_id}, string_view{ref_id}, ref_depth, string_view{ref_room.room_id}, std::get(top), sound_depth, twain_depth, fetching.size(), }; ref_top = std::max(ref_top, ref_idx); ret |= submitted; return true; }); assert(ref_top >= ref_min); ref_min = ref_top; return ret; } void ircd::m::acquire::acquire_timeline() { // We only enter this routine if the options are sufficient. Otherwise // the functionality here will overlap with acquire_history() and be // a more expensive form of the same thing. const bool sufficient_options { false || !opts.history || opts.viewport_size || opts.depth.first || opts.depth.second }; if(!sufficient_options) return; event::idx ref_min { opts.ref.first }; for(size_t i(0); i < opts.rounds; ++i) { if(!fetch_timeline(ref_min)) break; if(ref_min > opts.ref.second) break; } } bool ircd::m::acquire::fetch_timeline(event::idx &ref_min) { bool ret(false); auto _ref_min(ref_min); std::set pe; std::deque pq; event::idx _event_idx; if(opts.room.event_id) if((_event_idx = m::index(std::nothrow, opts.room.event_id))) pq.emplace_back(_event_idx); if(pq.empty()) m::room::head(opts.room).for_each([&pq] (const auto &event_idx, const auto &event_id) { pq.emplace_back(event_idx); return pq.size() < event::prev::MAX; }); if(pq.empty()) pq.emplace_back(m::head_idx(opts.room)); size_t submits(0); size_t leaf_ctr(0); m::event::fetch e, p; do { const auto ref_idx { pq.front() }; pq.pop_front(); if(ref_idx < opts.ref.first || ref_idx < ref_min) continue; if(ref_idx > opts.ref.second) continue; if(!seek(std::nothrow, e, ref_idx)) continue; const event::prev prev{e}; event::id _prev_id[prev.MAX]; const auto &prev_id { prev.ids(_prev_id) }; assert(prev_id.size() <= prev.MAX); event::idx _prev_idx[prev.MAX]; const auto prev_idx { prev.idxs(_prev_idx) }; size_t fetched(0); for(size_t i(0); i < prev_idx.size(); ++i) { if(prev_idx[i]) continue; const bool submitted { submit(prev_id[i], opts.hint, false, 1, &history_vmopts) }; if(!submitted) continue; log::debug { log, "Fetch from %s (%lu) miss prev %s fetch:%zu in %s pe:%zu pq:%zu fetching:%zu", string_view{e.event_id}, ref_idx, string_view{prev_id[i]}, fetched, string_view{opts.room.room_id}, pe.size(), pq.size(), fetching.size(), }; ++fetched; ++submits; ret |= true; } if(pq.size() >= (opts.leaf_depth?: prev.MAX)) continue; if(opts.leaf_depth || opts.viewport_size) { if(prev_id.size() == 1) { if(++leaf_ctr % (opts.viewport_size?: opts.leaf_depth) == 0) continue; } else leaf_ctr = 0; } size_t pushed(0); for(size_t i(0); i < prev_idx.size(); ++i) { if(!prev_idx[i]) continue; auto it(pe.lower_bound(prev_idx[i])); if(it != end(pe) && *it == prev_idx[i]) continue; pe.emplace_hint(it, prev_idx[i]); if(opts.depth.first || opts.depth.second) { const auto depth { m::get(std::nothrow, prev_idx[i], "depth", 0L) }; if(depth < opts.depth.first) continue; if(opts.depth.second && depth > opts.depth.second) continue; } pq.emplace_back(prev_idx[i]); _ref_min = std::max(_ref_min, prev_idx[i]); ++pushed; log::debug { log, "Queue from %s (%lu) next prev %s (%lu) push:%zu in %s pe:%zu pq:%zu fetching:%zu", string_view{e.event_id}, ref_idx, string_view{prev_id[i]}, prev_idx[i], pushed, string_view{opts.room.room_id}, pe.size(), pq.size(), fetching.size(), }; } } while(!pq.empty() && submits < opts.fetch_max); log::debug { log, "Round in %s pe:%zu pq:%zu submits:%zu fetching:%zu ref_min:%lu:%lu", string_view{opts.room.room_id}, pe.size(), pq.size(), submits, fetching.size(), ref_min, _ref_min, }; ref_min = std::max(ref_min, _ref_min); return ret; } void ircd::m::acquire::acquire_state() { m::event::id::buf event_id; if(opts.room.event_id) event_id = opts.room.event_id; if(!event_id && opts.viewport_size) event_id = m::event_id(std::nothrow, m::viewport(opts.room).second); //TODO: opts.viewport_size if(!event_id && opts.history) event_id = m::event_id(std::nothrow, m::sounding(opts.room).second); if(!event_id && opts.head) event_id = m::head(opts.room); if(!event_id) return; m::room::state::fetch::opts sfopts; sfopts.room.room_id = opts.room.room_id; sfopts.room.event_id = event_id; m::room::state::fetch { sfopts, [this](const m::event::id &event_id, const string_view &remote) { return fetch_state(event_id, remote); } }; } bool ircd::m::acquire::fetch_state(const m::event::id &event_id, const string_view &remote) { // Bail if interrupted if(ctx::interruption_requested()) return false; const auto hint { event_id.host() && !my_host(event_id.host())? event_id.host(): remote && !my_host(remote)? remote: opts.room.room_id.host() && !my_host(opts.room.room_id.host())? opts.room.room_id.host(): string_view{} }; const bool submitted { submit(event_id, hint, false, 1, &state_vmopts) }; if(submitted) log::debug { log, "Fetch %s in state of %s fetching:%zu", string_view{event_id}, string_view{opts.room.room_id}, fetching.size(), }; return true; } void ircd::m::acquire::acquire_head() { m::room::head::fetch::opts hfopts; hfopts.room_id = opts.room.room_id; hfopts.top = m::top(opts.room.room_id); m::room::head::fetch { hfopts, [this, &hfopts](const m::event &result) { const auto &[top_id, top_depth, top_idx] { hfopts.top }; return fetch_head(result, top_depth); } }; } bool ircd::m::acquire::fetch_head(const m::event &result, const int64_t &top_depth) { // Bail if interrupted if(ctx::interruption_requested()) return false; // Bail if the depth is below the window if(json::get<"depth"_>(result) < opts.depth.first) return false; const auto gap { json::get<"depth"_>(result) - top_depth }; const auto &limit { std::clamp(gap, 1L, 48L) }; const auto &hint { json::get<"origin"_>(result) }; const bool submitted { submit(result.event_id, hint, true, limit, &head_vmopts) }; if(submitted) log::debug { log, "Fetch %s head from '%s' in %s @%lu fetching:%zu", string_view{result.event_id}, hint, string_view{opts.room.room_id}, top_depth, fetching.size(), }; return true; } bool ircd::m::acquire::submit(const m::event::id &event_id, const string_view &hint, const bool &hint_only, const size_t &limit, const vm::opts *const &vmopts) { const bool ret { !started(event_id)? start(event_id, hint, hint_only, limit, vmopts): false }; if(ret || full()) while(handle()); return ret; } bool ircd::m::acquire::start(const m::event::id &event_id, const string_view &hint, const bool &hint_only, const size_t &limit, const vm::opts *const &vmopts) try { assert(vmopts); fetch::opts fopts; fopts.room_id = opts.room.room_id; fopts.event_id = event_id; fopts.backfill_limit = limit; fopts.op = (limit > 1 || hint)? fetch::op::backfill: fetch::op::event; fopts.hint = hint; fopts.attempt_limit = !hint_only? opts.attempt_max: 1U; fetching.emplace_back(result { vmopts, fetch::start(fopts), event_id }); return true; } catch(const ctx::interrupted &e) { throw; } catch(const std::exception &e) { log::error { log, "Fetch %s in %s from '%s' :%s", string_view{event_id}, string_view{opts.room.room_id}, hint?: ""_sv, e.what(), }; return false; } bool ircd::m::acquire::started(const event::id &event_id) const { const auto it { std::find_if(std::begin(fetching), std::end(fetching), [&event_id] (const auto &result) { return result.event_id == event_id; }) }; return it != std::end(fetching); } bool ircd::m::acquire::handle() { if(fetching.empty()) return false; auto next { ctx::when_any(std::begin(fetching), std::end(fetching), [] (auto &it) -> ctx::future & { return it->future; }) }; const milliseconds timeout { full()? 5000: 50 }; ctx::interruption_point(); if(!next.wait(timeout, std::nothrow)) return full(); const unique_iterator it { fetching, next.get() }; assert(it.it != std::end(fetching)); return handle(*it.it); } bool ircd::m::acquire::handle(result &result) try { auto response { result.future.get() }; const json::object body { response }; const json::array pdus { body["pdus"] }; log::debug { log, "Eval %zu from '%s' for %s in %s", pdus.size(), string_view{response.origin}, string_view{result.event_id}, string_view{opts.room.room_id}, }; assert(result.vmopts); assert ( false || result.vmopts == &this->head_vmopts || result.vmopts == &this->history_vmopts || result.vmopts == &this->state_vmopts ); auto vmopts(*result.vmopts); vmopts.node_id = response.origin; m::vm::eval { pdus, vmopts }; return true; } catch(const ctx::interrupted &e) { throw; } catch(const std::exception &e) { log::error { log, "Eval %s in %s :%s", string_view{result.event_id}, string_view{opts.room.room_id}, e.what(), }; return true; } bool ircd::m::acquire::full() const noexcept { return fetching.size() >= opts.fetch_width; }