# frozen_string_literal: true # Copyright, 2017, by Samuel G. D. Williams. # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN # THE SOFTWARE. require_relative 'logger' require_relative 'task' require_relative 'wrapper' require 'nio' require 'timers' require 'forwardable' module Async # Raised if a timeout occurs on a specific Fiber. Handled gracefully by `Task`. class TimeoutError < StandardError end # An asynchronous, cooperatively scheduled event reactor. class Reactor < Node extend Forwardable # The preferred method to invoke asynchronous behavior at the top level. # # - When invoked within an existing reactor task, it will run the given block # asynchronously. Will return the task once it has been scheduled. # - When invoked at the top level, will create and run a reactor, and invoke # the block as an asynchronous task. Will block until the reactor finishes # running. def self.run(*arguments, **options, &block) if current = Task.current? reactor = current.reactor return reactor.async(*arguments, **options, &block) else reactor = self.new begin return reactor.run(*arguments, **options, &block) ensure reactor.close end end end def self.selector if backend = ENV['ASYNC_BACKEND']&.to_sym if NIO::Selector.backends.include?(backend) return NIO::Selector.new(backend) else warn "Could not find ASYNC_BACKEND=#{backend}!" end end return NIO::Selector.new end def initialize(parent = nil, selector: self.class.selector, logger: nil) super(parent) @selector = selector @timers = Timers::Group.new @logger = logger @ready = [] @running = [] @interrupted = false @guard = Mutex.new end def logger @logger || Console.logger end def to_s "\#<#{self.description} #{@children&.size || 0} children (#{stopped? ? 'stopped' : 'running'})>" end def stopped? @children.nil? end # Start an asynchronous task within the specified reactor. The task will be # executed until the first blocking call, at which point it will yield and # and this method will return. # # This is the main entry point for scheduling asynchronus tasks. # # @yield [Task] Executed within the task. # @return [Task] The task that was scheduled into the reactor. def async(*arguments, **options, &block) task = Task.new(self, **options, &block) # I want to take a moment to explain the logic of this. # When calling an async block, we deterministically execute it until the # first blocking operation. We don't *have* to do this - we could schedule # it for later execution, but it's useful to: # - Fail at the point of the method call where possible. # - Execute determinstically where possible. # - Avoid scheduler overhead if no blocking operation is performed. task.run(*arguments) # logger.debug "Initial execution of task #{fiber} complete (#{result} -> #{fiber.alive?})..." return task end def register(io, interest, value = Fiber.current) monitor = @selector.register(io, interest) monitor.value = value return monitor end # Interrupt the reactor at the earliest convenience. Can be called from a different thread safely. def interrupt @guard.synchronize do unless @interrupted @interrupted = true @selector.wakeup end end end # Schedule a fiber (or equivalent object) to be resumed on the next loop through the reactor. # @param fiber [#resume] The object to be resumed on the next iteration of the run-loop. def << fiber @ready << fiber end # Yield the current fiber and resume it on the next iteration of the event loop. def yield(fiber = Fiber.current) @ready << fiber Fiber.yield end def finished? # TODO I'm not sure if checking `@running.empty?` is really required. super && @ready.empty? && @running.empty? end # Run one iteration of the event loop. # @param timeout [Float | nil] the maximum timeout, or if nil, indefinite. # @return [Boolean] whether there is more work to do. def run_once(timeout = nil) # logger.debug(self) {"@ready = #{@ready} @running = #{@running}"} if @ready.any? # running used to correctly answer on `finished?`, and to reuse Array object. @running, @ready = @ready, @running @running.each do |fiber| fiber.resume if fiber.alive? end @running.clear end if @ready.empty? interval = @timers.wait_interval else # if there are tasks ready to execute, don't sleep: interval = 0 end # If we are finished, we stop the task tree and exit: if self.finished? return false end # If there is no interval to wait (thus no timers), and no tasks, we could be done: if interval.nil? # Allow the user to specify a maximum interval if we would otherwise be sleeping indefinitely: interval = timeout elsif interval < 0 # We have timers ready to fire, don't sleep in the selctor: interval = 0 elsif timeout and interval > timeout interval = timeout end # logger.debug(self) {"Selecting with #{@children&.size} children with interval = #{interval ? interval.round(2) : 'infinite'}..."} if monitors = @selector.select(interval) monitors.each do |monitor| monitor.value.resume end end @timers.fire # We check and clear the interrupted flag here: if @interrupted @guard.synchronize do @interrupted = false end return false end # The reactor still has work to do: return true end # Run the reactor until all tasks are finished. Proxies arguments to {#async} immediately before entering the loop, if a block is provided. def run(*arguments, **options, &block) raise RuntimeError, 'Reactor has been closed' if @selector.nil? initial_task = self.async(*arguments, **options, &block) if block_given? while self.run_once # Round and round we go! end return initial_task ensure logger.debug(self) {"Exiting run-loop because #{$! ? $! : 'finished'}."} end def stop(later = true) @children&.each do |child| # We don't want this process to propagate `Async::Stop` exceptions, so we schedule tasks to stop later. child.stop(later) end end # Stop each of the children tasks and close the selector. # # @return [void] def close # This is a critical step. Because tasks could be stored as instance variables, and since the reactor is (probably) going out of scope, we need to ensure they are stopped. Otherwise, the tasks will belong to a reactor that will never run again and are not stopped. self.stop(false) @selector.close @selector = nil end # Check if the selector has been closed. # @return [Boolean] def closed? @selector.nil? end # Put the calling fiber to sleep for a given ammount of time. # @param duration [Numeric] The time in seconds, to sleep for. def sleep(duration) fiber = Fiber.current timer = @timers.after(duration) do if fiber.alive? fiber.resume end end Task.yield ensure timer.cancel if timer end # Invoke the block, but after the specified timeout, raise {TimeoutError} in any currenly blocking operation. If the block runs to completion before the timeout occurs or there are no non-blocking operations after the timeout expires, the code will complete without any exception. # @param duration [Numeric] The time in seconds, in which the task should # complete. def with_timeout(timeout, exception = TimeoutError) fiber = Fiber.current timer = @timers.after(timeout) do if fiber.alive? error = exception.new("execution expired") fiber.resume error end end yield timer ensure timer.cancel if timer end end end