/** This module contains the core functionality of the vibe.d framework. Copyright: © 2012-2020 Sönke Ludwig License: Subject to the terms of the MIT license, as written in the included LICENSE.txt file. Authors: Sönke Ludwig */ module vibe.core.core; public import vibe.core.task; import eventcore.core; import vibe.core.args; import vibe.core.concurrency; import vibe.core.internal.release; import vibe.core.log; import vibe.core.sync : ManualEvent, createSharedManualEvent; import vibe.core.taskpool : TaskPool; import vibe.internal.async; import vibe.internal.array : FixedRingBuffer; //import vibe.utils.array; import std.algorithm; import std.conv; import std.encoding; import core.exception; import std.exception; import std.functional; import std.range : empty, front, popFront; import std.string; import std.traits : isFunctionPointer; import std.typecons : Flag, Yes, Typedef, Tuple, tuple; import core.atomic; import core.sync.condition; import core.sync.mutex; import core.stdc.stdlib; import core.thread; version(Posix) { import core.sys.posix.signal; import core.sys.posix.unistd; import core.sys.posix.pwd; static if (__traits(compiles, {import core.sys.posix.grp; getgrgid(0);})) { import core.sys.posix.grp; } else { extern (C) { struct group { char* gr_name; char* gr_passwd; gid_t gr_gid; char** gr_mem; } group* getgrgid(gid_t); group* getgrnam(in char*); } } } version (Windows) { import core.stdc.signal; } /**************************************************************************************************/ /* Public functions */ /**************************************************************************************************/ /** Performs final initialization and runs the event loop. This function performs three tasks: $(OL $(LI Makes sure that no unrecognized command line options are passed to the application and potentially displays command line help. See also `vibe.core.args.finalizeCommandLineOptions`.) $(LI Performs privilege lowering if required.) $(LI Runs the event loop and blocks until it finishes.) ) Params: args_out = Optional parameter to receive unrecognized command line arguments. If left to `null`, an error will be reported if any unrecognized argument is passed. See_also: ` vibe.core.args.finalizeCommandLineOptions`, `lowerPrivileges`, `runEventLoop` */ int runApplication(string[]* args_out = null) @safe { try if (!() @trusted { return finalizeCommandLineOptions(args_out); } () ) return 0; catch (Exception e) { logDiagnostic("Error processing command line: %s", e.msg); return 1; } lowerPrivileges(); logDiagnostic("Running event loop..."); int status; version (VibeDebugCatchAll) { try { status = runEventLoop(); } catch( Throwable th ){ logError("Unhandled exception in event loop: %s", th.msg); logDiagnostic("Full exception: %s", th.toString().sanitize()); return 1; } } else { status = runEventLoop(); } logDiagnostic("Event loop exited with status %d.", status); return status; } /// A simple echo server, listening on a privileged TCP port. unittest { import vibe.core.core; import vibe.core.net; int main() { // first, perform any application specific setup (privileged ports still // available if run as root) listenTCP(7, (conn) { try conn.write(conn); catch (Exception e) { /* log error */ } }); // then use runApplication to perform the remaining initialization and // to run the event loop return runApplication(); } } /** The same as above, but performing the initialization sequence manually. This allows to skip any additional initialization (opening the listening port) if an invalid command line argument or the `--help` switch is passed to the application. */ unittest { import vibe.core.core; import vibe.core.net; int main() { // process the command line first, to be able to skip the application // setup if not required if (!finalizeCommandLineOptions()) return 0; // then set up the application listenTCP(7, (conn) { try conn.write(conn); catch (Exception e) { /* log error */ } }); // finally, perform privilege lowering (safe to skip for non-server // applications) lowerPrivileges(); // and start the event loop return runEventLoop(); } } /** Starts the vibe.d event loop for the calling thread. Note that this function is usually called automatically by the vibe.d framework. However, if you provide your own `main()` function, you may need to call either this or `runApplication` manually. The event loop will by default continue running during the whole life time of the application, but calling `runEventLoop` multiple times in sequence is allowed. Tasks will be started and handled only while the event loop is running. Returns: The returned value is the suggested code to return to the operating system from the `main` function. See_Also: `runApplication` */ int runEventLoop() @safe nothrow { setupSignalHandlers(); logDebug("Starting event loop."); s_eventLoopRunning = true; scope (exit) { eventDriver.core.clearExitFlag(); s_eventLoopRunning = false; s_exitEventLoop = false; if (s_isMainThread) atomicStore(st_term, false); () @trusted nothrow { scope (failure) assert(false); // notifyAll is not marked nothrow st_threadShutdownCondition.notifyAll(); } (); } // runs any yield()ed tasks first assert(!s_exitEventLoop, "Exit flag set before event loop has started."); s_exitEventLoop = false; performIdleProcessing(); if (getExitFlag()) return 0; Task exit_task; // handle exit flag in the main thread to exit when // exitEventLoop(true) is called from a thread) () @trusted nothrow { if (s_isMainThread) exit_task = runTask(toDelegate(&watchExitFlag)); } (); while (true) { auto er = s_scheduler.waitAndProcess(); if (er != ExitReason.idle || s_exitEventLoop) { logDebug("Event loop exit reason (exit flag=%s): %s", s_exitEventLoop, er); break; } performIdleProcessing(); } // make sure the exit flag watch task finishes together with this loop // TODO: would be nice to do this without exceptions if (exit_task && exit_task.running) exit_task.interrupt(); logDebug("Event loop done (scheduled tasks=%s, waiters=%s, thread exit=%s).", s_scheduler.scheduledTaskCount, eventDriver.core.waiterCount, s_exitEventLoop); return 0; } /** Stops the currently running event loop. Calling this function will cause the event loop to stop event processing and the corresponding call to runEventLoop() will return to its caller. Params: shutdown_all_threads = If true, exits event loops of all threads - false by default. Note that the event loops of all threads are automatically stopped when the main thread exits, so usually there is no need to set shutdown_all_threads to true. */ void exitEventLoop(bool shutdown_all_threads = false) @safe nothrow { logDebug("exitEventLoop called (%s)", shutdown_all_threads); assert(s_eventLoopRunning || shutdown_all_threads, "Exiting event loop when none is running."); if (shutdown_all_threads) { () @trusted nothrow { shutdownWorkerPool(); atomicStore(st_term, true); st_threadsSignal.emit(); } (); } // shutdown the calling thread s_exitEventLoop = true; if (s_eventLoopRunning) eventDriver.core.exit(); } /** Process all pending events without blocking. Checks if events are ready to trigger immediately, and run their callbacks if so. Returns: Returns false $(I iff) exitEventLoop was called in the process. */ bool processEvents() @safe nothrow { return !s_scheduler.process().among(ExitReason.exited, ExitReason.outOfWaiters); } /** Wait once for events and process them. */ ExitReason runEventLoopOnce() @safe nothrow { auto ret = s_scheduler.waitAndProcess(); if (ret == ExitReason.idle) performIdleProcessing(); return ret; } /** Sets a callback that is called whenever no events are left in the event queue. The callback delegate is called whenever all events in the event queue have been processed. Returning true from the callback will cause another idle event to be triggered immediately after processing any events that have arrived in the meantime. Returning false will instead wait until another event has arrived first. */ void setIdleHandler(void delegate() @safe nothrow del) @safe nothrow { s_idleHandler = () @safe nothrow { del(); return false; }; } /// ditto void setIdleHandler(bool delegate() @safe nothrow del) @safe nothrow { s_idleHandler = del; } /** Runs a new asynchronous task. task will be called synchronously from within the vibeRunTask call. It will continue to run until vibeYield() or any of the I/O or wait functions is called. Note that the maximum size of all args must not exceed `maxTaskParameterSize`. */ Task runTask(ARGS...)(void delegate(ARGS) @safe task, auto ref ARGS args) { return runTask_internal!((ref tfi) { tfi.set(task, args); }); } /// ditto Task runTask(ARGS...)(void delegate(ARGS) @system task, auto ref ARGS args) @system { return runTask_internal!((ref tfi) { tfi.set(task, args); }); } /// ditto Task runTask(CALLABLE, ARGS...)(CALLABLE task, auto ref ARGS args) if (!is(CALLABLE : void delegate(ARGS)) && is(typeof(CALLABLE.init(ARGS.init)))) { return runTask_internal!((ref tfi) { tfi.set(task, args); }); } /// ditto Task runTask(ARGS...)(TaskSettings settings, void delegate(ARGS) @safe task, auto ref ARGS args) { return runTask_internal!((ref tfi) { tfi.settings = settings; tfi.set(task, args); }); } /// ditto Task runTask(ARGS...)(TaskSettings settings, void delegate(ARGS) @system task, auto ref ARGS args) @system { return runTask_internal!((ref tfi) { tfi.settings = settings; tfi.set(task, args); }); } /// ditto Task runTask(CALLABLE, ARGS...)(TaskSettings settings, CALLABLE task, auto ref ARGS args) if (!is(CALLABLE : void delegate(ARGS)) && is(typeof(CALLABLE.init(ARGS.init)))) { return runTask_internal!((ref tfi) { tfi.settings = settings; tfi.set(task, args); }); } unittest { // test proportional priority scheduling auto tm = setTimer(1000.msecs, { assert(false, "Test timeout"); }); scope (exit) tm.stop(); size_t a, b; auto t1 = runTask(TaskSettings(1), { while (a + b < 100) { a++; yield(); } }); auto t2 = runTask(TaskSettings(10), { while (a + b < 100) { b++; yield(); } }); runTask({ t1.join(); t2.join(); exitEventLoop(); }); runEventLoop(); assert(a + b == 100); assert(b.among(90, 91, 92)); // expect 1:10 ratio +-1 } /** Runs an asyncronous task that is guaranteed to finish before the caller's scope is left. */ auto runTaskScoped(FT, ARGS)(scope FT callable, ARGS args) { static struct S { Task handle; @disable this(this); ~this() { handle.joinUninterruptible(); } } return S(runTask(callable, args)); } package Task runTask_internal(alias TFI_SETUP)() { import std.typecons : Tuple, tuple; TaskFiber f; while (!f && !s_availableFibers.empty) { f = s_availableFibers.back; s_availableFibers.popBack(); if (() @trusted nothrow { return f.state; } () != Fiber.State.HOLD) f = null; } if (f is null) { // if there is no fiber available, create one. if (s_availableFibers.capacity == 0) s_availableFibers.capacity = 1024; logDebugV("Creating new fiber..."); f = new TaskFiber; } TFI_SETUP(f.m_taskFunc); f.bumpTaskCounter(); auto handle = f.task(); debug if (TaskFiber.ms_taskCreationCallback) { TaskCreationInfo info; info.handle = handle; info.functionPointer = () @trusted { return cast(void*)f.m_taskFunc.functionPointer; } (); () @trusted { TaskFiber.ms_taskCreationCallback(info); } (); } debug if (TaskFiber.ms_taskEventCallback) { () @trusted { TaskFiber.ms_taskEventCallback(TaskEvent.preStart, handle); } (); } s_scheduler.switchTo(handle, TaskFiber.getThis().m_yieldLockCount > 0 ? Flag!"defer".yes : Flag!"defer".no); debug if (TaskFiber.ms_taskEventCallback) { () @trusted { TaskFiber.ms_taskEventCallback(TaskEvent.postStart, handle); } (); } return handle; } unittest { // ensure task.running is true directly after runTask Task t; bool hit = false; { auto l = yieldLock(); t = runTask({ hit = true; }); assert(!hit); assert(t.running); } t.join(); assert(!t.running); assert(hit); } /** Runs a new asynchronous task in a worker thread. Only function pointers with weakly isolated arguments are allowed to be able to guarantee thread-safety. */ void runWorkerTask(FT, ARGS...)(FT func, auto ref ARGS args) if (isFunctionPointer!FT) { setupWorkerThreads(); st_workerPool.runTask(func, args); } /// ditto void runWorkerTask(alias method, T, ARGS...)(shared(T) object, auto ref ARGS args) if (is(typeof(__traits(getMember, object, __traits(identifier, method))))) { setupWorkerThreads(); st_workerPool.runTask!method(object, args); } /// ditto void runWorkerTask(FT, ARGS...)(TaskSettings settings, FT func, auto ref ARGS args) if (isFunctionPointer!FT) { setupWorkerThreads(); st_workerPool.runTask(settings, func, args); } /// ditto void runWorkerTask(alias method, T, ARGS...)(TaskSettings settings, shared(T) object, auto ref ARGS args) if (is(typeof(__traits(getMember, object, __traits(identifier, method))))) { setupWorkerThreads(); st_workerPool.runTask!method(settings, object, args); } /** Runs a new asynchronous task in a worker thread, returning the task handle. This function will yield and wait for the new task to be created and started in the worker thread, then resume and return it. Only function pointers with weakly isolated arguments are allowed to be able to guarantee thread-safety. */ Task runWorkerTaskH(FT, ARGS...)(FT func, auto ref ARGS args) if (isFunctionPointer!FT) { setupWorkerThreads(); return st_workerPool.runTaskH(func, args); } /// ditto Task runWorkerTaskH(alias method, T, ARGS...)(shared(T) object, auto ref ARGS args) if (is(typeof(__traits(getMember, object, __traits(identifier, method))))) { setupWorkerThreads(); return st_workerPool.runTaskH!method(object, args); } /// ditto Task runWorkerTaskH(FT, ARGS...)(TaskSettings settings, FT func, auto ref ARGS args) if (isFunctionPointer!FT) { setupWorkerThreads(); return st_workerPool.runTaskH(settings, func, args); } /// ditto Task runWorkerTaskH(alias method, T, ARGS...)(TaskSettings settings, shared(T) object, auto ref ARGS args) if (is(typeof(__traits(getMember, object, __traits(identifier, method))))) { setupWorkerThreads(); return st_workerPool.runTaskH!method(settings, object, args); } /// Running a worker task using a function unittest { static void workerFunc(int param) { logInfo("Param: %s", param); } static void test() { runWorkerTask(&workerFunc, 42); runWorkerTask(&workerFunc, cast(ubyte)42); // implicit conversion #719 runWorkerTaskDist(&workerFunc, 42); runWorkerTaskDist(&workerFunc, cast(ubyte)42); // implicit conversion #719 } } /// Running a worker task using a class method unittest { static class Test { void workerMethod(int param) shared { logInfo("Param: %s", param); } } static void test() { auto cls = new shared Test; runWorkerTask!(Test.workerMethod)(cls, 42); runWorkerTask!(Test.workerMethod)(cls, cast(ubyte)42); // #719 runWorkerTaskDist!(Test.workerMethod)(cls, 42); runWorkerTaskDist!(Test.workerMethod)(cls, cast(ubyte)42); // #719 } } /// Running a worker task using a function and communicating with it unittest { static void workerFunc(Task caller) { int counter = 10; while (receiveOnly!string() == "ping" && --counter) { logInfo("pong"); caller.send("pong"); } caller.send("goodbye"); } static void test() { Task callee = runWorkerTaskH(&workerFunc, Task.getThis); do { logInfo("ping"); callee.send("ping"); } while (receiveOnly!string() == "pong"); } static void work719(int) {} static void test719() { runWorkerTaskH(&work719, cast(ubyte)42); } } /// Running a worker task using a class method and communicating with it unittest { static class Test { void workerMethod(Task caller) shared { int counter = 10; while (receiveOnly!string() == "ping" && --counter) { logInfo("pong"); caller.send("pong"); } caller.send("goodbye"); } } static void test() { auto cls = new shared Test; Task callee = runWorkerTaskH!(Test.workerMethod)(cls, Task.getThis()); do { logInfo("ping"); callee.send("ping"); } while (receiveOnly!string() == "pong"); } static class Class719 { void work(int) shared {} } static void test719() { auto cls = new shared Class719; runWorkerTaskH!(Class719.work)(cls, cast(ubyte)42); } } unittest { // run and join local task from outside of a task int i = 0; auto t = runTask({ sleep(1.msecs); i = 1; }); t.join(); assert(i == 1); } unittest { // run and join worker task from outside of a task __gshared int i = 0; auto t = runWorkerTaskH({ sleep(5.msecs); i = 1; }); t.join(); assert(i == 1); } /** Runs a new asynchronous task in all worker threads concurrently. This function is mainly useful for long-living tasks that distribute their work across all CPU cores. Only function pointers with weakly isolated arguments are allowed to be able to guarantee thread-safety. The number of tasks started is guaranteed to be equal to `workerThreadCount`. */ void runWorkerTaskDist(FT, ARGS...)(FT func, auto ref ARGS args) if (is(typeof(*func) == function)) { setupWorkerThreads(); return st_workerPool.runTaskDist(func, args); } /// ditto void runWorkerTaskDist(alias method, T, ARGS...)(shared(T) object, ARGS args) { setupWorkerThreads(); return st_workerPool.runTaskDist!method(object, args); } /// ditto void runWorkerTaskDist(FT, ARGS...)(TaskSettings settings, FT func, auto ref ARGS args) if (is(typeof(*func) == function)) { setupWorkerThreads(); return st_workerPool.runTaskDist(settings, func, args); } /// ditto void runWorkerTaskDist(alias method, T, ARGS...)(TaskSettings settings, shared(T) object, ARGS args) { setupWorkerThreads(); return st_workerPool.runTaskDist!method(settings, object, args); } /** Runs a new asynchronous task in all worker threads and returns the handles. `on_handle` is a callble that takes a `Task` as its only argument and is called for every task instance that gets created. See_also: `runWorkerTaskDist` */ void runWorkerTaskDistH(HCB, FT, ARGS...)(scope HCB on_handle, FT func, auto ref ARGS args) if (is(typeof(*func) == function)) { setupWorkerThreads(); st_workerPool.runTaskDistH(on_handle, func, args); } /// ditto void runWorkerTaskDistH(HCB, FT, ARGS...)(TaskSettings settings, scope HCB on_handle, FT func, auto ref ARGS args) if (is(typeof(*func) == function)) { setupWorkerThreads(); st_workerPool.runTaskDistH(settings, on_handle, func, args); } /** Sets up num worker threads. This function gives explicit control over the number of worker threads. Note, to have an effect the function must be called prior to related worker tasks functions which set up the default number of worker threads implicitly. Params: num = The number of worker threads to initialize. Defaults to `logicalProcessorCount`. See_also: `runWorkerTask`, `runWorkerTaskH`, `runWorkerTaskDist` */ public void setupWorkerThreads(uint num = logicalProcessorCount()) @safe { static bool s_workerThreadsStarted = false; if (s_workerThreadsStarted) return; s_workerThreadsStarted = true; () @trusted { synchronized (st_threadsMutex) { if (!st_workerPool) st_workerPool = new shared TaskPool(num); } } (); } /** Determines the number of logical processors in the system. This number includes virtual cores on hyper-threading enabled CPUs. */ public @property uint logicalProcessorCount() { import std.parallelism : totalCPUs; return totalCPUs; } /** Suspends the execution of the calling task to let other tasks and events be handled. Calling this function in short intervals is recommended if long CPU computations are carried out by a task. It can also be used in conjunction with Signals to implement cross-fiber events with no polling. Throws: May throw an `InterruptException` if `Task.interrupt()` gets called on the calling task. */ void yield() @safe { auto t = Task.getThis(); if (t != Task.init) { auto tf = () @trusted { return t.taskFiber; } (); tf.handleInterrupt(); s_scheduler.yield(); tf.handleInterrupt(); } else { // Let yielded tasks execute assert(TaskFiber.getThis().m_yieldLockCount == 0, "May not yield within an active yieldLock()!"); () @safe nothrow { performIdleProcessingOnce(true); } (); } } unittest { size_t ti; auto t = runTask({ for (ti = 0; ti < 10; ti++) yield(); }); foreach (i; 0 .. 5) yield(); assert(ti > 0 && ti < 10, "Task did not interleave with yield loop outside of task"); t.join(); assert(ti == 10); } /** Suspends the execution of the calling task until `switchToTask` is called manually. This low-level scheduling function is usually only used internally. Failure to call `switchToTask` will result in task starvation and resource leakage. Params: on_interrupt = If specified, is required to See_Also: `switchToTask` */ void hibernate(scope void delegate() @safe nothrow on_interrupt = null) @safe nothrow { auto t = Task.getThis(); if (t == Task.init) { assert(TaskFiber.getThis().m_yieldLockCount == 0, "May not yield within an active yieldLock!"); runEventLoopOnce(); } else { auto tf = () @trusted { return t.taskFiber; } (); tf.handleInterrupt(on_interrupt); s_scheduler.hibernate(); tf.handleInterrupt(on_interrupt); } } /** Switches execution to the given task. This function can be used in conjunction with `hibernate` to wake up a task. The task must live in the same thread as the caller. See_Also: `hibernate` */ void switchToTask(Task t) @safe nothrow { import std.typecons : Yes, No; auto defer = TaskFiber.getThis().m_yieldLockCount > 0 ? Yes.defer : No.defer; s_scheduler.switchTo(t, defer); } /** Suspends the execution of the calling task for the specified amount of time. Note that other tasks of the same thread will continue to run during the wait time, in contrast to $(D core.thread.Thread.sleep), which shouldn't be used in vibe.d applications. Throws: May throw an `InterruptException` if the task gets interrupted using `Task.interrupt()`. */ void sleep(Duration timeout) @safe { assert(timeout >= 0.seconds, "Argument to sleep must not be negative."); if (timeout <= 0.seconds) return; auto tm = setTimer(timeout, null); tm.wait(); } /// unittest { import vibe.core.core : sleep; import vibe.core.log : logInfo; import core.time : msecs; void test() { logInfo("Sleeping for half a second..."); sleep(500.msecs); logInfo("Done sleeping."); } } /** Returns a new armed timer. Note that timers can only work if an event loop is running, explicitly or implicitly by running a blocking operation, such as `sleep` or `File.read`. Params: timeout = Determines the minimum amount of time that elapses before the timer fires. callback = If non-`null`, this delegate will be called when the timer fires periodic = Speficies if the timer fires repeatedly or only once Returns: Returns a Timer object that can be used to identify and modify the timer. See_also: `createTimer` */ Timer setTimer(Duration timeout, Timer.Callback callback, bool periodic = false) @safe nothrow { auto tm = createTimer(callback); tm.rearm(timeout, periodic); return tm; } /// unittest { void printTime() @safe nothrow { import std.datetime; logInfo("The time is: %s", Clock.currTime()); } void test() { import vibe.core.core; // start a periodic timer that prints the time every second setTimer(1.seconds, toDelegate(&printTime), true); } } /// Compatibility overload - use a `@safe nothrow` callback instead. Timer setTimer(Duration timeout, void delegate() callback, bool periodic = false) @system nothrow { return setTimer(timeout, () @trusted nothrow { try callback(); catch (Exception e) { logWarn("Timer callback failed: %s", e.msg); scope (failure) assert(false); logDebug("Full error: %s", e.toString().sanitize); } }, periodic); } /** Creates a new timer without arming it. Each time `callback` gets invoked, it will be run inside of a newly started task. Params: callback = If non-`null`, this delegate will be called when the timer fires See_also: `createLeanTimer`, `setTimer` */ Timer createTimer(void delegate() nothrow @safe callback = null) @safe nothrow { static struct C { void delegate() nothrow @safe callback; void opCall() nothrow @safe { runTask(callback); } } if (callback) { C c = {callback}; return createLeanTimer(c); } return createLeanTimer!(Timer.Callback)(null); } /** Creates a new timer with a lean callback mechanism. In contrast to the standard `createTimer`, `callback` will not be called in a new task, but is instead called directly in the context of the event loop. For this reason, the supplied callback is not allowed to perform any operation that needs to block/yield execution. In this case, `runTask` needs to be used explicitly to perform the operation asynchronously. Additionally, `callback` can carry arbitrary state without requiring a heap allocation. See_also: `createTimer` */ Timer createLeanTimer(CALLABLE)(CALLABLE callback) if (is(typeof(() @safe nothrow { callback(); } ()))) { return Timer.create(eventDriver.timers.create(), callback); } /** Creates an event to wait on an existing file descriptor. The file descriptor usually needs to be a non-blocking socket for this to work. Params: file_descriptor = The Posix file descriptor to watch event_mask = Specifies which events will be listened for Returns: Returns a newly created FileDescriptorEvent associated with the given file descriptor. */ FileDescriptorEvent createFileDescriptorEvent(int file_descriptor, FileDescriptorEvent.Trigger event_mask) @safe nothrow { return FileDescriptorEvent(file_descriptor, event_mask); } /** Sets the stack size to use for tasks. The default stack size is set to 512 KiB on 32-bit systems and to 16 MiB on 64-bit systems, which is sufficient for most tasks. Tuning this value can be used to reduce memory usage for large numbers of concurrent tasks or to avoid stack overflows for applications with heavy stack use. Note that this function must be called at initialization time, before any task is started to have an effect. Also note that the stack will initially not consume actual physical memory - it just reserves virtual address space. Only once the stack gets actually filled up with data will physical memory then be reserved page by page. This means that the stack can safely be set to large sizes on 64-bit systems without having to worry about memory usage. */ void setTaskStackSize(size_t sz) nothrow { TaskFiber.ms_taskStackSize = sz; } /** The number of worker threads used for processing worker tasks. Note that this function will cause the worker threads to be started, if they haven't already. See_also: `runWorkerTask`, `runWorkerTaskH`, `runWorkerTaskDist`, `setupWorkerThreads` */ @property size_t workerThreadCount() out(count) { assert(count > 0, "No worker threads started after setupWorkerThreads!?"); } body { setupWorkerThreads(); synchronized (st_threadsMutex) return st_workerPool.threadCount; } /** Disables the signal handlers usually set up by vibe.d. During the first call to `runEventLoop`, vibe.d usually sets up a set of event handlers for SIGINT, SIGTERM and SIGPIPE. Since in some situations this can be undesirable, this function can be called before the first invocation of the event loop to avoid this. Calling this function after `runEventLoop` will have no effect. */ void disableDefaultSignalHandlers() { synchronized (st_threadsMutex) s_disableSignalHandlers = true; } /** Sets the effective user and group ID to the ones configured for privilege lowering. This function is useful for services run as root to give up on the privileges that they only need for initialization (such as listening on ports <= 1024 or opening system log files). */ void lowerPrivileges(string uname, string gname) @safe { if (!isRoot()) return; if (uname != "" || gname != "") { static bool tryParse(T)(string s, out T n) { import std.conv, std.ascii; if (!isDigit(s[0])) return false; n = parse!T(s); return s.length==0; } int uid = -1, gid = -1; if (uname != "" && !tryParse(uname, uid)) uid = getUID(uname); if (gname != "" && !tryParse(gname, gid)) gid = getGID(gname); setUID(uid, gid); } else logWarn("Vibe was run as root, and no user/group has been specified for privilege lowering. Running with full permissions."); } // ditto void lowerPrivileges() @safe { lowerPrivileges(s_privilegeLoweringUserName, s_privilegeLoweringGroupName); } /** Sets a callback that is invoked whenever a task changes its status. This function is useful mostly for implementing debuggers that analyze the life time of tasks, including task switches. Note that the callback will only be called for debug builds. */ void setTaskEventCallback(TaskEventCallback func) { debug TaskFiber.ms_taskEventCallback = func; } /** Sets a callback that is invoked whenever new task is created. The callback is guaranteed to be invoked before the one set by `setTaskEventCallback` for the same task handle. This function is useful mostly for implementing debuggers that analyze the life time of tasks, including task switches. Note that the callback will only be called for debug builds. */ void setTaskCreationCallback(TaskCreationCallback func) { debug TaskFiber.ms_taskCreationCallback = func; } /** A version string representing the current vibe.d core version */ enum vibeVersionString = "1.8.1"; /** Generic file descriptor event. This kind of event can be used to wait for events on a non-blocking file descriptor. Note that this can usually only be used on socket based file descriptors. */ struct FileDescriptorEvent { /** Event mask selecting the kind of events to listen for. */ enum Trigger { none = 0, /// Match no event (invalid value) read = 1<<0, /// React on read-ready events write = 1<<1, /// React on write-ready events any = read|write /// Match any kind of event } private { static struct Context { Trigger trigger; shared(NativeEventDriver) driver; } StreamSocketFD m_socket; Context* m_context; } @safe: private this(int fd, Trigger event_mask) nothrow { m_socket = eventDriver.sockets.adoptStream(fd); m_context = () @trusted { return &eventDriver.sockets.userData!Context(m_socket); } (); m_context.trigger = event_mask; m_context.driver = () @trusted { return cast(shared)eventDriver; } (); } this(this) nothrow { if (m_socket != StreamSocketFD.invalid) eventDriver.sockets.addRef(m_socket); } ~this() nothrow { if (m_socket != StreamSocketFD.invalid) releaseHandle!"sockets"(m_socket, m_context.driver); } /** Waits for the selected event to occur. Params: which = Optional event mask to react only on certain events timeout = Maximum time to wait for an event Returns: The overload taking the timeout parameter returns true if an event was received on time and false otherwise. */ void wait(Trigger which = Trigger.any) { wait(Duration.max, which); } /// ditto bool wait(Duration timeout, Trigger which = Trigger.any) { if ((which & m_context.trigger) == Trigger.none) return true; assert((which & m_context.trigger) == Trigger.read, "Waiting for write event not yet supported."); bool got_data; alias readwaiter = Waitable!(IOCallback, cb => eventDriver.sockets.waitForData(m_socket, cb), cb => eventDriver.sockets.cancelRead(m_socket), (fd, st, nb) { got_data = st == IOStatus.ok; } ); asyncAwaitAny!(true, readwaiter)(timeout); return got_data; } } /** Represents a timer. */ struct Timer { private { NativeEventDriver m_driver; TimerID m_id; debug uint m_magicNumber = 0x4d34f916; } alias Callback = void delegate() @safe nothrow; @safe: private static Timer create(CALLABLE)(TimerID id, CALLABLE callback) nothrow { assert(id != TimerID.init, "Invalid timer ID."); Timer ret; ret.m_driver = eventDriver; ret.m_id = id; static if (is(typeof(!callback))) if (!callback) return ret; ret.m_driver.timers.userData!CALLABLE(id) = callback; ret.m_driver.timers.wait(id, &TimerCallbackHandler!CALLABLE.instance.handle); return ret; } this(this) nothrow { debug assert(m_magicNumber == 0x4d34f916, "Timer corrupted."); if (m_driver) m_driver.timers.addRef(m_id); } ~this() nothrow { debug assert(m_magicNumber == 0x4d34f916, "Timer corrupted."); if (m_driver) releaseHandle!"timers"(m_id, () @trusted { return cast(shared)m_driver; } ()); } /// True if the timer is yet to fire. @property bool pending() nothrow { return m_driver.timers.isPending(m_id); } /// The internal ID of the timer. @property size_t id() const nothrow { return m_id; } bool opCast() const nothrow { return m_driver !is null; } /// Determines if this reference is the only one @property bool unique() const nothrow { return m_driver ? m_driver.timers.isUnique(m_id) : false; } /** Resets the timer to the specified timeout */ void rearm(Duration dur, bool periodic = false) nothrow in { assert(dur > 0.seconds, "Negative timer duration specified."); } body { m_driver.timers.set(m_id, dur, periodic ? dur : 0.seconds); } /** Resets the timer and avoids any firing. */ void stop() nothrow { if (m_driver) m_driver.timers.stop(m_id); } /** Waits until the timer fires. This method may only be used if no timer callback has been specified. Returns: `true` is returned $(I iff) the timer was fired. */ bool wait() { auto cb = m_driver.timers.userData!Callback(m_id); assert(cb is null, "Cannot wait on a timer that was created with a callback."); auto res = asyncAwait!(TimerCallback2, cb => m_driver.timers.wait(m_id, cb), cb => m_driver.timers.cancelWait(m_id) ); return res[1]; } } private struct TimerCallbackHandler(CALLABLE) { static __gshared TimerCallbackHandler ms_instance; static @property ref TimerCallbackHandler instance() @trusted nothrow { return ms_instance; } void handle(TimerID timer, bool fired) @safe nothrow { if (fired) { auto cb = eventDriver.timers.userData!CALLABLE(timer); auto l = yieldLock(); cb(); } if (!eventDriver.timers.isUnique(timer) || eventDriver.timers.isPending(timer)) eventDriver.timers.wait(timer, &handle); } } /** Returns an object that ensures that no task switches happen during its life time. Any attempt to run the event loop or switching to another task will cause an assertion to be thrown within the scope that defines the lifetime of the returned object. Multiple yield locks can appear in nested scopes. */ auto yieldLock() @safe nothrow { static struct YieldLock { @safe nothrow: private bool m_initialized; private this(bool) { m_initialized = true; inc(); } @disable this(this); ~this() { if (m_initialized) dec(); } private void inc() { TaskFiber.getThis().m_yieldLockCount++; } private void dec() { assert(TaskFiber.getThis().m_yieldLockCount > 0); TaskFiber.getThis().m_yieldLockCount--; } } return YieldLock(true); } unittest { auto tf = TaskFiber.getThis(); assert(tf.m_yieldLockCount == 0); { auto lock = yieldLock(); assert(tf.m_yieldLockCount == 1); { auto lock2 = yieldLock(); assert(tf.m_yieldLockCount == 2); } assert(tf.m_yieldLockCount == 1); } assert(tf.m_yieldLockCount == 0); { typeof(yieldLock()) l; assert(tf.m_yieldLockCount == 0); } assert(tf.m_yieldLockCount == 0); } /**************************************************************************************************/ /* private types */ /**************************************************************************************************/ private void setupGcTimer() { s_gcTimer = createTimer(() @trusted { import core.memory; logTrace("gc idle collect"); GC.collect(); GC.minimize(); s_ignoreIdleForGC = true; }); s_gcCollectTimeout = dur!"seconds"(2); } package(vibe) void performIdleProcessing(bool force_process_events = false) @safe nothrow { bool again = !getExitFlag(); while (again) { again = performIdleProcessingOnce(force_process_events); force_process_events = true; } if (s_scheduler.scheduledTaskCount) logDebug("Exiting from idle processing although there are still yielded tasks"); if (s_exitEventLoop) return; if (!s_ignoreIdleForGC && s_gcTimer) { s_gcTimer.rearm(s_gcCollectTimeout); } else s_ignoreIdleForGC = false; } private bool performIdleProcessingOnce(bool process_events) @safe nothrow { if (process_events) { auto er = eventDriver.core.processEvents(0.seconds); if (er.among!(ExitReason.exited, ExitReason.outOfWaiters) && s_scheduler.scheduledTaskCount == 0) { if (s_eventLoopRunning) { logDebug("Setting exit flag due to driver signalling exit: %s", er); s_exitEventLoop = true; } return false; } } bool again; if (s_idleHandler) again = s_idleHandler(); return (s_scheduler.schedule() == ScheduleStatus.busy || again) && !getExitFlag(); } private struct ThreadContext { Thread thread; } /**************************************************************************************************/ /* private functions */ /**************************************************************************************************/ private { Duration s_gcCollectTimeout; Timer s_gcTimer; bool s_ignoreIdleForGC = false; __gshared core.sync.mutex.Mutex st_threadsMutex; shared TaskPool st_workerPool; shared ManualEvent st_threadsSignal; __gshared ThreadContext[] st_threads; __gshared Condition st_threadShutdownCondition; shared bool st_term = false; bool s_isMainThread = false; // set in shared static this bool s_exitEventLoop = false; package bool s_eventLoopRunning = false; bool delegate() @safe nothrow s_idleHandler; TaskScheduler s_scheduler; FixedRingBuffer!TaskFiber s_availableFibers; size_t s_maxRecycledFibers = 100; string s_privilegeLoweringUserName; string s_privilegeLoweringGroupName; __gshared bool s_disableSignalHandlers = false; } private bool getExitFlag() @trusted nothrow { return s_exitEventLoop || atomicLoad(st_term); } package @property bool isEventLoopRunning() @safe nothrow @nogc { return s_eventLoopRunning; } package @property ref TaskScheduler taskScheduler() @safe nothrow @nogc { return s_scheduler; } package void recycleFiber(TaskFiber fiber) @safe nothrow { if (s_availableFibers.length >= s_maxRecycledFibers) { auto fl = s_availableFibers.front; s_availableFibers.popFront(); fl.shutdown(); () @trusted { try destroy(fl); catch (Exception e) logWarn("Failed to destroy fiber: %s", e.msg); } (); } if (s_availableFibers.full) s_availableFibers.capacity = 2 * s_availableFibers.capacity; s_availableFibers.put(fiber); } private void setupSignalHandlers() @trusted nothrow { scope (failure) assert(false); // _d_monitorexit is not nothrow __gshared bool s_setup = false; // only initialize in main thread synchronized (st_threadsMutex) { if (s_setup) return; s_setup = true; if (s_disableSignalHandlers) return; logTrace("setup signal handler"); version(Posix){ // support proper shutdown using signals sigset_t sigset; sigemptyset(&sigset); sigaction_t siginfo; siginfo.sa_handler = &onSignal; siginfo.sa_mask = sigset; siginfo.sa_flags = SA_RESTART; sigaction(SIGINT, &siginfo, null); sigaction(SIGTERM, &siginfo, null); siginfo.sa_handler = &onBrokenPipe; sigaction(SIGPIPE, &siginfo, null); } version(Windows){ // WORKAROUND: we don't care about viral @nogc attribute here! import std.traits; signal(SIGTERM, cast(ParameterTypeTuple!signal[1])&onSignal); signal(SIGINT, cast(ParameterTypeTuple!signal[1])&onSignal); } } } // per process setup shared static this() { version(Windows){ version(VibeLibeventDriver) enum need_wsa = true; else version(VibeWin32Driver) enum need_wsa = true; else enum need_wsa = false; static if (need_wsa) { logTrace("init winsock"); // initialize WinSock2 import core.sys.windows.winsock2; WSADATA data; WSAStartup(0x0202, &data); } } s_isMainThread = true; // COMPILER BUG: Must be some kind of module constructor order issue: // without this, the stdout/stderr handles are not initialized before // the log module is set up. import std.stdio; File f; f.close(); initializeLogModule(); logTrace("create driver core"); st_threadsMutex = new Mutex; st_threadShutdownCondition = new Condition(st_threadsMutex); auto thisthr = Thread.getThis(); thisthr.name = "main"; assert(st_threads.length == 0, "Main thread not the first thread!?"); st_threads ~= ThreadContext(thisthr); st_threadsSignal = createSharedManualEvent(); version(VibeIdleCollect) { logTrace("setup gc"); setupGcTimer(); } version (VibeNoDefaultArgs) {} else { readOption("uid|user", &s_privilegeLoweringUserName, "Sets the user name or id used for privilege lowering."); readOption("gid|group", &s_privilegeLoweringGroupName, "Sets the group name or id used for privilege lowering."); } import std.concurrency; scheduler = new VibedScheduler; } shared static ~this() { shutdownDriver(); size_t tasks_left = s_scheduler.scheduledTaskCount; if (tasks_left > 0) logWarn("There were still %d tasks running at exit.", tasks_left); } // per thread setup static this() { /// workaround for: // object.Exception@src/rt/minfo.d(162): Aborting: Cycle detected between modules with ctors/dtors: // vibe.core.core -> vibe.core.drivers.native -> vibe.core.drivers.libasync -> vibe.core.core if (Thread.getThis().isDaemon && Thread.getThis().name == "CmdProcessor") return; auto thisthr = Thread.getThis(); synchronized (st_threadsMutex) if (!st_threads.any!(c => c.thread is thisthr)) st_threads ~= ThreadContext(thisthr); } static ~this() { auto thisthr = Thread.getThis(); bool is_main_thread = s_isMainThread; synchronized (st_threadsMutex) { auto idx = st_threads.countUntil!(c => c.thread is thisthr); logDebug("Thread exit %s (index %s) (main=%s)", thisthr.name, idx, is_main_thread); } if (is_main_thread) { logDiagnostic("Main thread exiting"); shutdownWorkerPool(); } synchronized (st_threadsMutex) { auto idx = st_threads.countUntil!(c => c.thread is thisthr); assert(idx >= 0, "No more threads registered"); if (idx >= 0) { st_threads[idx] = st_threads[$-1]; st_threads.length--; } } // delay deletion of the main event driver to "~shared static this()" if (!is_main_thread) shutdownDriver(); st_threadShutdownCondition.notifyAll(); } private void shutdownWorkerPool() nothrow { shared(TaskPool) tpool; try synchronized (st_threadsMutex) swap(tpool, st_workerPool); catch (Exception e) assert(false, e.msg); if (tpool) { logDiagnostic("Still waiting for worker threads to exit."); tpool.terminate(); } } private void shutdownDriver() { if (ManualEvent.ms_threadEvent != EventID.init) { eventDriver.events.releaseRef(ManualEvent.ms_threadEvent); ManualEvent.ms_threadEvent = EventID.init; } eventDriver.dispose(); } private void watchExitFlag() { auto emit_count = st_threadsSignal.emitCount; while (true) { synchronized (st_threadsMutex) { if (getExitFlag()) break; } try emit_count = st_threadsSignal.wait(emit_count); catch (InterruptException e) return; } logDebug("main thread exit"); eventDriver.core.exit(); } private extern(C) void extrap() @safe nothrow { logTrace("exception trap"); } private extern(C) void onSignal(int signal) nothrow { logInfo("Received signal %d. Shutting down.", signal); atomicStore(st_term, true); try st_threadsSignal.emit(); catch (Throwable th) { logDebug("Failed to notify for event loop exit: %s", th.msg); } } private extern(C) void onBrokenPipe(int signal) nothrow { logTrace("Broken pipe."); } version(Posix) { private bool isRoot() @trusted { return geteuid() == 0; } private void setUID(int uid, int gid) @trusted { logInfo("Lowering privileges to uid=%d, gid=%d...", uid, gid); if (gid >= 0) { enforce(getgrgid(gid) !is null, "Invalid group id!"); enforce(setegid(gid) == 0, "Error setting group id!"); } //if( initgroups(const char *user, gid_t group); if (uid >= 0) { enforce(getpwuid(uid) !is null, "Invalid user id!"); enforce(seteuid(uid) == 0, "Error setting user id!"); } } private int getUID(string name) @trusted { auto pw = getpwnam(name.toStringz()); enforce(pw !is null, "Unknown user name: "~name); return pw.pw_uid; } private int getGID(string name) @trusted { auto gr = getgrnam(name.toStringz()); enforce(gr !is null, "Unknown group name: "~name); return gr.gr_gid; } } else version(Windows){ private bool isRoot() @safe { return false; } private void setUID(int uid, int gid) @safe { enforce(false, "UID/GID not supported on Windows."); } private int getUID(string name) @safe { enforce(false, "Privilege lowering not supported on Windows."); assert(false); } private int getGID(string name) @safe { enforce(false, "Privilege lowering not supported on Windows."); assert(false); } }