// Matrix Construct // // Copyright (C) Matrix Construct Developers, Authors & Contributors // Copyright (C) 2016-2018 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. namespace ircd { // Fundamental context #1; all subsystems live as objects on this stack. // This is created by ircd::init(), and it executes ircd::main(), it then // deletes itself and nulls this pointer when finished. extern ctx::ctx *main_context; // Main function. This frame anchors the initialization and destruction of // all non-static assets provided by the library. static void main() noexcept; } // internal interface to ircd::run (see ircd/run.h, ircd/run.cc) namespace ircd::run { // change the current runlevel bool set(const enum level &); } /// Records compile-time header version information. decltype(ircd::version_api) ircd::version_api { "IRCd", info::versions::API, 0, {0, 0, 0}, RB_VERSION }; /// Records runtime linked library (this library) version information. decltype(ircd::version_abi) ircd::version_abi { "IRCd", info::versions::ABI, 0, {0, 0, 0}, ircd::info::version }; /// Courtesy indicator; this item allows the library to indicate to the /// embedder that they should restart their application (or reload this library /// if available). The use-case here is for features like the `restart` command /// in the console module. Such a command triggers a normal quit and the /// application may exit normally; therefor the embedder should check this /// item to perform a restart rather than exiting. decltype(ircd::restart) ircd::restart { { "name", "ircd.restart" }, { "default", false }, { "persist", false }, }; /// Coarse mode indicator for debug/developer behavior when and if possible. /// For example: additional log messages may be enabled by this mode. This /// option is technically effective in both release builds and debug builds /// but it controls far less in non-debug builds. This item may be toggled /// at any time. It doesn't change operational functionality. decltype(ircd::debugmode) ircd::debugmode { { "name", "ircd.debugmode" }, { "default", false }, { "persist", false }, }; /// When assertions are enabled this further softens runtime behavior to be /// non-disruptive/non-terminating for diagnostic purposes. Debugging/developer /// use only. This item may be toggled at any time. decltype(ircd::soft_assert) ircd::soft_assert { { "name", "ircd.soft_assert" }, { "default", false }, { "persist", false }, }; /// Coarse mode declaration for "maintenance mode" a.k.a. "single user mode" /// which is intended to be similar to normal operating mode but without /// services to clients or some background tasks. It is implied and set when /// write_avoid=true which is itself implied and set by read_only. decltype(ircd::maintenance) ircd::maintenance { { { "name", "ircd.maintenance" }, { "default", false }, { "persist", false }, }, [] { if(!maintenance) return; net::listen.set("false"); } }; /// Coarse mode indicator for degraded operation known as "write-avoid" which /// is similar to read_only but not hard-enforced. Writes may still occur, /// such as those manually triggered by an admin. All subsystems and background /// tasks otherwise depart from normal operation to avoid writes. decltype(ircd::write_avoid) ircd::write_avoid { { { "name", "ircd.write_avoid" }, { "default", false }, { "persist", false }, }, [] { if(!write_avoid) return; maintenance.set("true"); db::auto_compact.set("false"); } }; /// Coarse mode declaration for read-only behavior. All subsystems and feature /// modules respect this indicator by preventing any writes and persistence /// during execution. This item should be set before ircd::init() to be most /// effective. decltype(ircd::read_only) ircd::read_only { { { "name", "ircd.read_only" }, { "default", false }, { "persist", false }, }, [] { if(!read_only) return; write_avoid.set("true"); } }; /// Diagnostic options selection. This indicates whether any tests or special /// behavior should occur rather than normal operation; also allowing for /// fine-grained options to be conveyed to such tests/diagnostics. While this /// appears here as coarse library-wide option it does not on its own affect /// normal server operations just by being set. It affect things only if /// specific functionality checks and alters its behavior based on the value /// of this string contextually. decltype(ircd::diagnostic) ircd::diagnostic { { "name", "ircd.diagnostic" }, { "default", string_view{} }, { "persist", false }, }; /// Main context pointer placement. decltype(ircd::main_context) ircd::main_context; /// Sets up the IRCd and its main context, then returns without blocking. /// /// Pass the executor obtained from your io_context instance. /// /// This function will setup the main program loop of libircd. The execution will /// occur when your io_context.run() or poll() is further invoked. /// /// init() can only be called from a run::level::HALT state void ircd::init(boost::asio::executor &&executor) try { // This function must only be called from a HALT state. if(run::level != run::level::HALT) throw error { "Cannot init() IRCd from runlevel %s", reflect(run::level) }; // Setup the core event loop system starting with the user's supplied ios. ios::init(std::move(executor)); // The log is available. but it is console-only until conf opens files. log::init(); log::mark("DEADSTART"); // 6600 // This starts off the log with library information. info::dump(); // Setup the main context, which is a new stack executing the function // ircd::main(). The main_context is the first ircd::ctx to be spawned // and will be the last to finish. // // The context::POST will delay this spawn until the next io_context // event slice, so no context switch will occur here. Note that POST has // to be used here because: A. This init() function is executing on the // main stack, and context switches can only occur between context stacks, // not between contexts and the main stack. B. The user's io_context may or // may not even be running yet anyway. // // (debug compilation) The context::SLICE_EXEMPT flag exempts the context // from assertions that it's not blocking the process with excessive CPU // usage or long syscall. Main context can't meet this requirement. // context main_context { "main", 256_KiB, &ircd::main, context::POST | context::SLICE_EXEMPT }; // The default behavior for ircd::context is to join the ctx on dtor. We // can't have that here because this is strictly an asynchronous function // on the main stack. Under normal circumstances, the mc will be entered // and be able to delete this pointer itself when it finishes. Otherwise // this must be manually deleted with assurance that mc will never enter. ircd::main_context = main_context.detach(); // Finally, without prior exception, the commitment to run::level::READY // is made here. The user can now invoke their ios.run(), or, if they // have already, IRCd will begin main execution shortly... run::set(run::level::READY); } catch(const std::exception &e) { throw; } /// Notifies IRCd to shutdown. A shutdown will occur asynchronously and this /// function will return immediately. A runlevel change to HALT will be /// indicated when IRCd has no more work for the ios. When the HALT state /// is observed the user is free to destruct all resources related to libircd. /// /// This function is the proper way to shutdown libircd after an init(), and while /// your io_context.run() is invoked without stopping your io_context shared by /// other activities unrelated to libircd. If your io_context has no other activities /// the run() will then return immediately after IRCd posts its transition to /// the HALT state. /// bool ircd::quit() noexcept { log::debug { "IRCd quit requested from runlevel:%s ctx:%p main_context:%p", reflect(run::level), (const void *)ctx::current, (const void *)main_context }; if(main_context) switch(run::level) { case run::level::READY: { ctx::terminate(*main_context); main_context = nullptr; ircd::run::set(run::level::HALT); return true; } case run::level::LOAD: case run::level::START: { ctx::terminate(*main_context); main_context = nullptr; return true; } case run::level::RUN: { ctx::notify(*main_context); main_context = nullptr; return true; } case run::level::UNLOAD: case run::level::QUIT: case run::level::HALT: case run::level::FAULT: return false; } return false; } /// Notifies IRCd that execution is being resumed after a significant gap. /// Basically this is connected to a SIGCONT handler and beneficial after /// user stops, debugging and ACPI suspensions, etc. It is not required at /// this time, but its connection is advised for best behavior. void ircd::cont() noexcept { log::debug { "IRCd cont requested from runlevel:%s ctx:%p main_context:%p", reflect(run::level), (const void *)ctx::current, (const void *)main_context }; switch(run::level) { case run::level::LOAD: case run::level::RUN: break; default: return; } log::notice { "IRCd resuming service in runlevel %s.", reflect(run::level), }; } /// Main context; Main program. Do not call this function directly. /// /// This function manages the lifetime for all resources and subsystems /// that don't/can't have their own static initialization. When this /// function is entered, subsystem init objects are constructed on the /// frame. The lifetime of those objects is the handle to the lifetime /// of the subsystem, so destruction will shut down that subsystem. /// /// The status of this function and IRCd overall can be observed through /// the ircd::runlevel. The ircd::run::changed callback can be set /// to be notified on a runlevel change. The user should wait for a runlevel /// of HALT before destroying IRCd related resources and stopping their /// io_context from running more jobs. /// void ircd::main() noexcept try { // When this function completes without exception, subsystems are done shutting down and IRCd // transitions to HALT. const unwind_defer halted{[] { run::set(run::level::HALT); }}; // When this function is entered IRCd will transition to START indicating // that subsystems are initializing. run::set(run::level::START); ctx::interruption_point(); // These objects are the init()'s and fini()'s for each subsystem. // Appearing here ties their life to the main context. Initialization can // also occur in ircd::init() or static initialization itself if either are // more appropriate. fs::init _fs_; // Local filesystem magic::init _magic_; // libmagic ctx::ole::init _ole_; // Thread OffLoad Engine magick::init _magick_; // ImageMagick openssl::init _ossl_; // openssl crypto net::init _net_; // Networking db::init _db_; // RocksDB client::init _client_; // Client related server::init _server_; // Server related js::init _js_; // SpiderMonkey // Transition to the QUIT and UNLOAD states on unwind. const unwind quit{[] { ircd::run::set(run::level::QUIT); ircd::run::set(run::level::UNLOAD); }}; ctx::interruption_point(); // IRCd will now transition to the LOAD state allowing library user's to // load their applications using the run::changed callback. run::set(run::level::LOAD); ctx::interruption_point(); // IRCd will now transition to the RUN state indicating full functionality. run::set(run::level::RUN); ctx::interruption_point(); // This call blocks until the main context is notified or interrupted etc. // Waiting here will hold open this stack with all of the above objects // living on it. ctx::wait(); } catch(const std::exception &e) { log::critical { "IRCd main :%s", e.what() }; } catch(const ctx::terminated &) { return; } catch(...) { log::critical { "IRCd main error." }; } /// IRCd uptime in seconds ircd::seconds ircd::uptime() { return seconds(ircd::time() - info::startup_time); }