mirror of
https://github.com/matrix-construct/construct
synced 2024-11-26 16:52:44 +01:00
660 lines
12 KiB
C++
660 lines
12 KiB
C++
// Matrix Construct
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//
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// Copyright (C) Matrix Construct Developers, Authors & Contributors
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// Copyright (C) 2016-2018 Jason Volk <jason@zemos.net>
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//
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// Permission to use, copy, modify, and/or distribute this software for any
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// purpose with or without fee is hereby granted, provided that the above
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// copyright notice and this permission notice is present in all copies. The
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// full license for this software is available in the LICENSE file.
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#include "sync.h"
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ircd::mapi::header
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IRCD_MODULE
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{
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"Client 6.2.1 :Sync"
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};
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decltype(ircd::m::sync::resource)
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ircd::m::sync::resource
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{
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"/_matrix/client/r0/sync",
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{
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description
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}
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};
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decltype(ircd::m::sync::description)
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ircd::m::sync::description
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{R"(6.2.1
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Synchronise the client's state with the latest state on the server. Clients
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use this API when they first log in to get an initial snapshot of the state
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on the server, and then continue to call this API to get incremental deltas
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to the state, and to receive new messages.
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)"};
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decltype(ircd::m::sync::flush_hiwat)
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ircd::m::sync::flush_hiwat
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{
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{ "name", "ircd.client.sync.flush.hiwat" },
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{ "default", long(48_KiB) },
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};
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decltype(ircd::m::sync::buffer_size)
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ircd::m::sync::buffer_size
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{
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{ "name", "ircd.client.sync.buffer_size" },
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{ "default", long(128_KiB) },
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};
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decltype(ircd::m::sync::linear_delta_max)
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ircd::m::sync::linear_delta_max
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{
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{ "name", "ircd.client.sync.linear.delta.max" },
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{ "default", 1024 },
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};
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//
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// GET sync
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//
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decltype(ircd::m::sync::method_get)
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ircd::m::sync::method_get
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{
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resource, "GET", handle_get,
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{
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method_get.REQUIRES_AUTH,
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-1s,
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}
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};
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ircd::resource::response
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ircd::m::sync::handle_get(client &client,
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const resource::request &request)
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{
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// Parse the request options
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const args args
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{
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request
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};
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// The range to `/sync`. We involve events starting at the range.first
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// index in this sync. We will not involve events with an index equal
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// or greater than the range.second. In this case the range.second does not
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// exist yet because it is one past the server's current_sequence counter.
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const m::events::range range
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{
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args.since, std::min(args.next_batch, m::vm::current_sequence + 1)
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};
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// When the range indexes are the same, the client is polling for the next
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// event which doesn't exist yet. There is no reason for the since parameter
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// to be greater than that.
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if(range.first > range.second)
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throw m::NOT_FOUND
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{
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"Since parameter is too far in the future..."
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};
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// Keep state for statistics of this sync here on the stack.
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stats stats;
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data data
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{
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request.user_id,
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range,
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&client,
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nullptr,
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&stats,
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args.filter_id
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};
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// Start the chunked encoded response.
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resource::response::chunked response
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{
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client, http::OK, buffer_size
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};
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json::stack out
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{
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response.buf,
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std::bind(&sync::flush, std::ref(data), std::ref(response), ph::_1),
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size_t(flush_hiwat)
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};
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data.out = &out;
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log::debug
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{
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log, "request %s", loghead(data)
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};
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const bool shortpolled
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{
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range.first > range.second?
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false:
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range.second - range.first <= size_t(linear_delta_max)?
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linear_handle(data):
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polylog_handle(data)
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};
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// When shortpoll was successful, do nothing else.
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if(shortpolled)
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return {};
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if(longpoll::poll(data, args))
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return {};
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// A user-timeout occurred. According to the spec we return a
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// 200 with empty fields rather than a 408.
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empty_response(data);
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return {};
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}
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void
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ircd::m::sync::empty_response(data &data)
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{
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json::stack::object top
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{
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*data.out
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};
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// Empty objects added to output otherwise Riot b0rks.
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json::stack::object
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{
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top, "rooms"
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};
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json::stack::object
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{
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top, "presence"
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};
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json::stack::member
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{
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top, "next_batch", json::value
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{
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lex_cast(data.range.second), json::STRING
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}
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};
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}
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ircd::const_buffer
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ircd::m::sync::flush(data &data,
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resource::response::chunked &response,
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const const_buffer &buffer)
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{
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const auto wrote
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{
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response.flush(buffer)
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};
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if(data.stats)
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{
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data.stats->flush_bytes += size(wrote);
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data.stats->flush_count++;
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}
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return wrote;
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}
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// polylog
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//
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// Random access approach for large `since` ranges. The /sync schema itself is
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// recursed. For every component in the schema, the handler seeks the events
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// appropriate for the user and appends it to the output. Concretely, this
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// involves a full iteration of the rooms a user is a member of, and a full
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// iteration of the presence status for all users visible to a user, etc.
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//
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// This entire process occurs in a single pass. The schema is traced with
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// json::stack and its buffer is flushed to the client periodically with
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// chunked encoding.
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bool
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ircd::m::sync::polylog_handle(data &data)
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try
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{
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json::stack::checkpoint checkpoint
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{
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*data.out
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};
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json::stack::object top
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{
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*data.out
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};
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bool ret{false};
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m::sync::for_each(string_view{}, [&data, &ret]
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(item &item)
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{
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json::stack::checkpoint checkpoint
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{
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*data.out
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};
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json::stack::object object
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{
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*data.out, item.member_name()
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};
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if(item.polylog(data))
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ret = true;
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else
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checkpoint.rollback();
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return true;
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});
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if(ret)
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json::stack::member
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{
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*data.out, "next_batch", json::value
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{
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lex_cast(data.range.second), json::STRING
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}
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};
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if(!ret)
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checkpoint.rollback();
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if(stats_info) log::info
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{
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log, "request %s polylog commit:%b complete",
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loghead(data),
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ret
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};
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return ret;
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}
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catch(const std::exception &e)
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{
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log::error
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{
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log, "polylog %s FAILED :%s",
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loghead(data),
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e.what()
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};
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throw;
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}
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//
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// linear
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//
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// Approach for small `since` ranges. The range of events is iterated and
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// the event itself is presented to each handler in the schema. This also
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// involves a json::stack trace of the schema so that if the handler determines
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// the event is appropriate for syncing to the user the output buffer will
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// contain a residue of a /sync response with a single event.
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//
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// After the iteration of events is complete we are left with several buffers
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// of properly formatted individual /sync responses which we rewrite into a
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// single response to overcome the inefficiency of request ping-pong under
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// heavy load.
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namespace ircd::m::sync
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{
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static bool linear_proffer_event_one(data &);
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static size_t linear_proffer_event(data &, const mutable_buffer &);
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static std::pair<event::idx, bool> linear_proffer(data &, window_buffer &);
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}
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bool
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ircd::m::sync::linear_handle(data &data)
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try
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{
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json::stack::checkpoint checkpoint
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{
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*data.out
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};
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json::stack::object top
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{
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*data.out
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};
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const unique_buffer<mutable_buffer> buf
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{
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96_KiB //TODO: XXX
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};
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window_buffer wb{buf};
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const auto &[last, completed]
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{
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linear_proffer(data, wb)
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};
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const json::vector vector
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{
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wb.completed()
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};
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if(last)
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{
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const auto next
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{
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completed?
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data.range.second:
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last + 1
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};
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json::stack::member
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{
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top, "next_batch", json::value
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{
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lex_cast(next), json::STRING
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}
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};
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json::merge(top, vector);
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}
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else checkpoint.rollback();
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log::debug
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{
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log, "request %s linear %lu:%lu complete:%b",
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loghead(data),
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data.range.first,
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last,
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completed
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};
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return last;
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}
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catch(const std::exception &e)
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{
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log::error
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{
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log, "linear %s FAILED :%s",
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loghead(data),
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e.what()
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};
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throw;
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}
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/// Iterates the events in the data.range and creates a json::vector in
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/// the supplied window_buffer. The return value is the event_idx of the
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/// last event which fit in the buffer, or 0 of nothing was of interest
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/// to our client in the event iteration.
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std::pair<ircd::m::event::idx, bool>
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ircd::m::sync::linear_proffer(data &data,
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window_buffer &wb)
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{
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event::idx ret(0);
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const auto closure{[&data, &wb, &ret]
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(const m::event::idx &event_idx, const m::event &event)
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{
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const scope_restore their_event
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{
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data.event, &event
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};
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const scope_restore their_event_idx
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{
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data.event_idx, event_idx
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};
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wb([&data, &ret, &event_idx]
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(const mutable_buffer &buf)
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{
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const auto consumed
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{
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linear_proffer_event(data, buf)
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};
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if(consumed)
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ret = event_idx;
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return consumed;
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});
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return wb.remaining() >= 65_KiB; //TODO: XXX
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}};
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const auto completed
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{
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m::events::for_each(data.range, closure)
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};
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return
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{
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ret, completed
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};
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}
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/// Sets up a json::stack for the iteration of handlers for
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/// one event.
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size_t
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ircd::m::sync::linear_proffer_event(data &data,
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const mutable_buffer &buf)
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{
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json::stack out{buf};
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const scope_restore their_out
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{
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data.out, &out
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};
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json::stack::object top
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{
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*data.out
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};
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const bool success
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{
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linear_proffer_event_one(data)
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};
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top.~object();
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return success?
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size(out.completed()):
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0UL;
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}
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/// Generates a candidate /sync response for a single event by
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/// iterating all of the handlers.
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bool
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ircd::m::sync::linear_proffer_event_one(data &data)
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{
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return !m::sync::for_each(string_view{}, [&data]
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(item &item)
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{
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json::stack::checkpoint checkpoint
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{
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*data.out
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};
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json::stack::object object
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{
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*data.out, item.member_name()
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};
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if(item.linear(data))
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return false;
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checkpoint.rollback();
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return true;
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});
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}
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//
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// longpoll
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//
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decltype(ircd::m::sync::longpoll::notified)
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ircd::m::sync::longpoll::notified
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{
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handle_notify,
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{
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{ "_site", "vm.notify" },
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}
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};
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void
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ircd::m::sync::longpoll::handle_notify(const m::event &event,
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m::vm::eval &eval)
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{
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assert(eval.opts);
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if(!eval.opts->notify_clients)
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return;
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if(!polling)
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{
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queue.clear();
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return;
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}
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queue.emplace_back(eval);
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dock.notify_all();
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}
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bool
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ircd::m::sync::longpoll::poll(data &data,
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const args &args)
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try
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{
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const scope_count polling{longpoll::polling}; do
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{
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if(!dock.wait_until(args.timesout))
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break;
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if(queue.empty())
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continue;
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const auto &accepted
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{
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queue.front()
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};
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const unwind pop{[]
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{
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if(longpoll::polling <= 1)
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queue.pop_front();
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}};
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if(handle(data, args, accepted))
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return true;
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}
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while(1);
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return false;
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}
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catch(const std::exception &e)
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{
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log::error
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{
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log, "longpoll %s FAILED :%s",
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loghead(data),
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e.what()
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};
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throw;
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}
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bool
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ircd::m::sync::longpoll::handle(data &data,
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const args &args,
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const accepted &event)
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{
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const scope_restore their_event
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{
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data.event, &event
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};
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const scope_restore their_event_idx
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{
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data.event_idx, event.event_idx
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};
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const scope_restore client_txnid
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{
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data.client_txnid, event.client_txnid
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};
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json::stack::checkpoint checkpoint
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{
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*data.out
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};
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json::stack::object top
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{
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*data.out
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};
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const bool ret
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{
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linear_proffer_event_one(data)
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};
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if(ret)
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{
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const auto next
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{
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data.range.second
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};
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json::stack::member
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{
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*data.out, "next_batch", json::value
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{
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lex_cast(next), json::STRING
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}
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};
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log::debug
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{
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log, "request %s longpoll got:%lu complete",
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loghead(data),
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event.event_idx
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};
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}
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else checkpoint.rollback();
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return ret;
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}
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//
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// sync/args.h
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//
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ircd::conf::item<ircd::milliseconds>
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ircd::m::sync::args::timeout_max
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{
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{ "name", "ircd.client.sync.timeout.max" },
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{ "default", 15 * 1000L },
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};
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ircd::conf::item<ircd::milliseconds>
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ircd::m::sync::args::timeout_min
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{
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{ "name", "ircd.client.sync.timeout.min" },
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{ "default", 5 * 1000L },
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};
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ircd::conf::item<ircd::milliseconds>
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ircd::m::sync::args::timeout_default
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{
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{ "name", "ircd.client.sync.timeout.default" },
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{ "default", 10 * 1000L },
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};
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//
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// args::args
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//
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|
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ircd::m::sync::args::args(const resource::request &request)
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try
|
|
:request
|
|
{
|
|
request
|
|
}
|
|
{
|
|
}
|
|
catch(const bad_lex_cast &e)
|
|
{
|
|
throw m::BAD_REQUEST
|
|
{
|
|
"Since parameter invalid :%s", e.what()
|
|
};
|
|
}
|