benchmarks/Richards/dart2/Richards.dart - sdk.git - Git at Google

 // Copyright 2006-2008 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // Ported by the Dart team to Dart.

 // This is a Dart implementation of the Richards benchmark from:
 //
 //    http://www.cl.cam.ac.uk/~mr10/Bench.html
 //
 // The benchmark was originally implemented in BCPL by
 // Martin Richards.

 // @dart=2.9

 import 'package:benchmark_harness/benchmark_harness.dart';

 void main() {
   const Richards().report();
 }

 /// Richards imulates the task dispatcher of an operating system.
 class Richards extends BenchmarkBase {
   const Richards() : super('Richards');

   @override
   void run() {
     final Scheduler scheduler = Scheduler();
     scheduler.addIdleTask(ID_IDLE, 0, null, COUNT);

     Packet queue = Packet(null, ID_WORKER, KIND_WORK);
     queue = Packet(queue, ID_WORKER, KIND_WORK);
     scheduler.addWorkerTask(ID_WORKER, 1000, queue);

     queue = Packet(null, ID_DEVICE_A, KIND_DEVICE);
     queue = Packet(queue, ID_DEVICE_A, KIND_DEVICE);
     queue = Packet(queue, ID_DEVICE_A, KIND_DEVICE);
     scheduler.addHandlerTask(ID_HANDLER_A, 2000, queue);

     queue = Packet(null, ID_DEVICE_B, KIND_DEVICE);
     queue = Packet(queue, ID_DEVICE_B, KIND_DEVICE);
     queue = Packet(queue, ID_DEVICE_B, KIND_DEVICE);
     scheduler.addHandlerTask(ID_HANDLER_B, 3000, queue);

     scheduler.addDeviceTask(ID_DEVICE_A, 4000, null);

     scheduler.addDeviceTask(ID_DEVICE_B, 5000, null);

     scheduler.schedule();

     if (scheduler.queueCount != EXPECTED_QUEUE_COUNT ||
         scheduler.holdCount != EXPECTED_HOLD_COUNT) {
       print('Error during execution: queueCount = ${scheduler.queueCount}'
           ', holdCount = ${scheduler.holdCount}.');
     }
     if (EXPECTED_QUEUE_COUNT != scheduler.queueCount) {
       throw 'bad scheduler queue-count';
     }
     if (EXPECTED_HOLD_COUNT != scheduler.holdCount) {
       throw 'bad scheduler hold-count';
     }
   }

   static const int DATA_SIZE = 4;
   static const int COUNT = 1000;

   /// These two constants specify how many times a packet is queued and
   /// how many times a task is put on hold in a correct run of richards.
   /// They don't have any meaning a such but are characteristic of a
   /// correct run so if the actual queue or hold count is different from
   /// the expected there must be a bug in the implementation.
   static const int EXPECTED_QUEUE_COUNT = 2322;
   static const int EXPECTED_HOLD_COUNT = 928;

   static const int ID_IDLE = 0;
   static const int ID_WORKER = 1;
   static const int ID_HANDLER_A = 2;
   static const int ID_HANDLER_B = 3;
   static const int ID_DEVICE_A = 4;
   static const int ID_DEVICE_B = 5;
   static const int NUMBER_OF_IDS = 6;

   static const int KIND_DEVICE = 0;
   static const int KIND_WORK = 1;
 }

 /// A scheduler can be used to schedule a set of tasks based on their relative
 /// priorities.  Scheduling is done by maintaining a list of task control blocks
 /// which holds tasks and the data queue they are processing.
 class Scheduler {
   int queueCount = 0;
   int holdCount = 0;
   TaskControlBlock currentTcb;
   int currentId;
   TaskControlBlock list;
   List<TaskControlBlock> blocks =
       List<TaskControlBlock>(Richards.NUMBER_OF_IDS);

   /// Add an idle task to this scheduler.
   void addIdleTask(int id, int priority, Packet queue, int count) {
     addRunningTask(id, priority, queue, IdleTask(this, 1, count));
   }

   /// Add a work task to this scheduler.
   void addWorkerTask(int id, int priority, Packet queue) {
     addTask(id, priority, queue, WorkerTask(this, Richards.ID_HANDLER_A, 0));
   }

   /// Add a handler task to this scheduler.
   void addHandlerTask(int id, int priority, Packet queue) {
     addTask(id, priority, queue, HandlerTask(this));
   }

   /// Add a handler task to this scheduler.
   void addDeviceTask(int id, int priority, Packet queue) {
     addTask(id, priority, queue, DeviceTask(this));
   }

   /// Add the specified task and mark it as running.
   void addRunningTask(int id, int priority, Packet queue, Task task) {
     addTask(id, priority, queue, task);
     currentTcb.setRunning();
   }

   /// Add the specified task to this scheduler.
   void addTask(int id, int priority, Packet queue, Task task) {
     currentTcb = TaskControlBlock(list, id, priority, queue, task);
     list = currentTcb;
     blocks[id] = currentTcb;
   }

   /// Execute the tasks managed by this scheduler.
   void schedule() {
     currentTcb = list;
     while (currentTcb != null) {
       if (currentTcb.isHeldOrSuspended()) {
         currentTcb = currentTcb.link;
       } else {
         currentId = currentTcb.id;
         currentTcb = currentTcb.run();
       }
     }
   }

   /// Release a task that is currently blocked and return the next block to run.
   TaskControlBlock release(int id) {
     final TaskControlBlock tcb = blocks[id];
     if (tcb == null) return tcb;
     tcb.markAsNotHeld();
     if (tcb.priority > currentTcb.priority) return tcb;
     return currentTcb;
   }

   /// Block the currently executing task and return the next task control block
   /// to run.  The blocked task will not be made runnable until it is explicitly
   /// released, even if new work is added to it.
   TaskControlBlock holdCurrent() {
     holdCount++;
     currentTcb.markAsHeld();
     return currentTcb.link;
   }

   /// Suspend the currently executing task and return the next task
   /// control block to run.
   /// If new work is added to the suspended task it will be made runnable.
   TaskControlBlock suspendCurrent() {
     currentTcb.markAsSuspended();
     return currentTcb;
   }

   /// Add the specified packet to the end of the worklist used by the task
   /// associated with the packet and make the task runnable if it is currently
   /// suspended.
   TaskControlBlock queue(Packet packet) {
     final TaskControlBlock t = blocks[packet.id];
     if (t == null) return t;
     queueCount++;
     packet.link = null;
     packet.id = currentId;
     return t.checkPriorityAdd(currentTcb, packet);
   }
 }

 /// A task control block manages a task and the queue of work packages
 /// associated with it.
 class TaskControlBlock {
   TaskControlBlock link;
   int id; // The id of this block.
   int priority; // The priority of this block.
   Packet queue; // The queue of packages to be processed by the task.
   Task task;
   int state;

   TaskControlBlock(this.link, this.id, this.priority, this.queue, this.task) {
     state = queue == null ? STATE_SUSPENDED : STATE_SUSPENDED_RUNNABLE;
   }

   /// The task is running and is currently scheduled.
   static const int STATE_RUNNING = 0;

   /// The task has packets left to process.
   static const int STATE_RUNNABLE = 1;

   /// The task is not currently running. The task is not blocked as such and may
   /// be started by the scheduler.
   static const int STATE_SUSPENDED = 2;

   /// The task is blocked and cannot be run until it is explicitly released.
   static const int STATE_HELD = 4;

   static const int STATE_SUSPENDED_RUNNABLE = STATE_SUSPENDED | STATE_RUNNABLE;
   static const int STATE_NOT_HELD = ~STATE_HELD;

   void setRunning() {
     state = STATE_RUNNING;
   }

   void markAsNotHeld() {
     state = state & STATE_NOT_HELD;
   }

   void markAsHeld() {
     state = state | STATE_HELD;
   }

   bool isHeldOrSuspended() {
     return (state & STATE_HELD) != 0 || (state == STATE_SUSPENDED);
   }

   void markAsSuspended() {
     state = state | STATE_SUSPENDED;
   }

   void markAsRunnable() {
     state = state | STATE_RUNNABLE;
   }

   /// Runs this task, if it is ready to be run, and returns the next
   /// task to run.
   TaskControlBlock run() {
     Packet packet;
     if (state == STATE_SUSPENDED_RUNNABLE) {
       packet = queue;
       queue = packet.link;
       state = queue == null ? STATE_RUNNING : STATE_RUNNABLE;
     } else {
       packet = null;
     }
     return task.run(packet);
   }

   /// Adds a packet to the worklist of this block's task, marks this as
   /// runnable if necessary, and returns the next runnable object to run
   /// (the one with the highest priority).
   TaskControlBlock checkPriorityAdd(TaskControlBlock task, Packet packet) {
     if (queue == null) {
       queue = packet;
       markAsRunnable();
       if (priority > task.priority) return this;
     } else {
       queue = packet.addTo(queue);
     }
     return task;
   }

   @override
   String toString() => 'tcb { $task@$state }';
 }

 ///  Abstract task that manipulates work packets.
 abstract class Task {
   Scheduler scheduler; // The scheduler that manages this task.

   Task(this.scheduler);

   TaskControlBlock run(Packet packet);
 }

 /// An idle task doesn't do any work itself but cycles control between the two
 /// device tasks.
 class IdleTask extends Task {
   int v1; // A seed value that controls how the device tasks are scheduled.
   int count; // The number of times this task should be scheduled.

   IdleTask(Scheduler scheduler, this.v1, this.count) : super(scheduler);

   @override
   TaskControlBlock run(Packet packet) {
     count--;
     if (count == 0) return scheduler.holdCurrent();
     if ((v1 & 1) == 0) {
       v1 = v1 >> 1;
       return scheduler.release(Richards.ID_DEVICE_A);
     }
     v1 = (v1 >> 1) ^ 0xD008;
     return scheduler.release(Richards.ID_DEVICE_B);
   }

   @override
   String toString() => 'IdleTask';
 }

 /// A task that suspends itself after each time it has been run to simulate
 /// waiting for data from an external device.
 class DeviceTask extends Task {
   Packet v1;

   DeviceTask(Scheduler scheduler) : super(scheduler);

   @override
   TaskControlBlock run(Packet packet) {
     if (packet == null) {
       if (v1 == null) return scheduler.suspendCurrent();
       final Packet v = v1;
       v1 = null;
       return scheduler.queue(v);
     }
     v1 = packet;
     return scheduler.holdCurrent();
   }

   @override
   String toString() => 'DeviceTask';
 }

 /// A task that manipulates work packets.
 class WorkerTask extends Task {
   int v1; // A seed used to specify how work packets are manipulated.
   int v2; // Another seed used to specify how work packets are manipulated.

   WorkerTask(Scheduler scheduler, this.v1, this.v2) : super(scheduler);

   @override
   TaskControlBlock run(Packet packet) {
     if (packet == null) {
       return scheduler.suspendCurrent();
     }
     if (v1 == Richards.ID_HANDLER_A) {
       v1 = Richards.ID_HANDLER_B;
     } else {
       v1 = Richards.ID_HANDLER_A;
     }
     packet.id = v1;
     packet.a1 = 0;
     for (int i = 0; i < Richards.DATA_SIZE; i++) {
       v2++;
       if (v2 > 26) v2 = 1;
       packet.a2[i] = v2;
     }
     return scheduler.queue(packet);
   }

   @override
   String toString() => 'WorkerTask';
 }

 /// A task that manipulates work packets and then suspends itself.
 class HandlerTask extends Task {
   Packet v1;
   Packet v2;

   HandlerTask(Scheduler scheduler) : super(scheduler);

   @override
   TaskControlBlock run(Packet packet) {
     if (packet != null) {
       if (packet.kind == Richards.KIND_WORK) {
         v1 = packet.addTo(v1);
       } else {
         v2 = packet.addTo(v2);
       }
     }
     if (v1 != null) {
       final int count = v1.a1;
       Packet v;
       if (count < Richards.DATA_SIZE) {
         if (v2 != null) {
           v = v2;
           v2 = v2.link;
           v.a1 = v1.a2[count];
           v1.a1 = count + 1;
           return scheduler.queue(v);
         }
       } else {
         v = v1;
         v1 = v1.link;
         return scheduler.queue(v);
       }
     }
     return scheduler.suspendCurrent();
   }

   @override
   String toString() => 'HandlerTask';
 }

 /// A simple package of data that is manipulated by the tasks.  The exact layout
 /// of the payload data carried by a packet is not importaint, and neither is
 /// the nature of the work performed on packets by the tasks. Besides carrying
 /// data, packets form linked lists and are hence used both as data and
 /// worklists.
 class Packet {
   Packet link; // The tail of the linked list of packets.
   int id; // An ID for this packet.
   int kind; // The type of this packet.
   int a1 = 0;

   List<int> a2 = List(Richards.DATA_SIZE);

   Packet(this.link, this.id, this.kind);

   /// Add this packet to the end of a worklist, and return the worklist.
   Packet addTo(Packet queue) {
     link = null;
     if (queue == null) return this;
     Packet peek, next = queue;
     while ((peek = next.link) != null) {
       next = peek;
     }
     next.link = this;
     return queue;
   }

   @override
   String toString() => 'Packet';
 }
	// Copyright 2006-2008 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// Ported by the Dart team to Dart.

	// This is a Dart implementation of the Richards benchmark from:
	//
	// http://www.cl.cam.ac.uk/~mr10/Bench.html
	//
	// The benchmark was originally implemented in BCPL by
	// Martin Richards.

	// @dart=2.9

	import 'package:benchmark_harness/benchmark_harness.dart';

	void main() {
	const Richards().report();
	}

	/// Richards imulates the task dispatcher of an operating system.
	class Richards extends BenchmarkBase {
	const Richards() : super('Richards');

	@override
	void run() {
	final Scheduler scheduler = Scheduler();
	scheduler.addIdleTask(ID_IDLE, 0, null, COUNT);

	Packet queue = Packet(null, ID_WORKER, KIND_WORK);
	queue = Packet(queue, ID_WORKER, KIND_WORK);
	scheduler.addWorkerTask(ID_WORKER, 1000, queue);

	queue = Packet(null, ID_DEVICE_A, KIND_DEVICE);
	queue = Packet(queue, ID_DEVICE_A, KIND_DEVICE);
	queue = Packet(queue, ID_DEVICE_A, KIND_DEVICE);
	scheduler.addHandlerTask(ID_HANDLER_A, 2000, queue);

	queue = Packet(null, ID_DEVICE_B, KIND_DEVICE);
	queue = Packet(queue, ID_DEVICE_B, KIND_DEVICE);
	queue = Packet(queue, ID_DEVICE_B, KIND_DEVICE);
	scheduler.addHandlerTask(ID_HANDLER_B, 3000, queue);

	scheduler.addDeviceTask(ID_DEVICE_A, 4000, null);

	scheduler.addDeviceTask(ID_DEVICE_B, 5000, null);

	scheduler.schedule();

	if (scheduler.queueCount != EXPECTED_QUEUE_COUNT \|\|
	scheduler.holdCount != EXPECTED_HOLD_COUNT) {
	print('Error during execution: queueCount = ${scheduler.queueCount}'
	', holdCount = ${scheduler.holdCount}.');
	}
	if (EXPECTED_QUEUE_COUNT != scheduler.queueCount) {
	throw 'bad scheduler queue-count';
	}
	if (EXPECTED_HOLD_COUNT != scheduler.holdCount) {
	throw 'bad scheduler hold-count';
	}
	}

	static const int DATA_SIZE = 4;
	static const int COUNT = 1000;

	/// These two constants specify how many times a packet is queued and
	/// how many times a task is put on hold in a correct run of richards.
	/// They don't have any meaning a such but are characteristic of a
	/// correct run so if the actual queue or hold count is different from
	/// the expected there must be a bug in the implementation.
	static const int EXPECTED_QUEUE_COUNT = 2322;
	static const int EXPECTED_HOLD_COUNT = 928;

	static const int ID_IDLE = 0;
	static const int ID_WORKER = 1;
	static const int ID_HANDLER_A = 2;
	static const int ID_HANDLER_B = 3;
	static const int ID_DEVICE_A = 4;
	static const int ID_DEVICE_B = 5;
	static const int NUMBER_OF_IDS = 6;

	static const int KIND_DEVICE = 0;
	static const int KIND_WORK = 1;
	}

	/// A scheduler can be used to schedule a set of tasks based on their relative
	/// priorities. Scheduling is done by maintaining a list of task control blocks
	/// which holds tasks and the data queue they are processing.
	class Scheduler {
	int queueCount = 0;
	int holdCount = 0;
	TaskControlBlock currentTcb;
	int currentId;
	TaskControlBlock list;
	List<TaskControlBlock> blocks =
	List<TaskControlBlock>(Richards.NUMBER_OF_IDS);

	/// Add an idle task to this scheduler.
	void addIdleTask(int id, int priority, Packet queue, int count) {
	addRunningTask(id, priority, queue, IdleTask(this, 1, count));
	}

	/// Add a work task to this scheduler.
	void addWorkerTask(int id, int priority, Packet queue) {
	addTask(id, priority, queue, WorkerTask(this, Richards.ID_HANDLER_A, 0));
	}

	/// Add a handler task to this scheduler.
	void addHandlerTask(int id, int priority, Packet queue) {
	addTask(id, priority, queue, HandlerTask(this));
	}

	/// Add a handler task to this scheduler.
	void addDeviceTask(int id, int priority, Packet queue) {
	addTask(id, priority, queue, DeviceTask(this));
	}

	/// Add the specified task and mark it as running.
	void addRunningTask(int id, int priority, Packet queue, Task task) {
	addTask(id, priority, queue, task);
	currentTcb.setRunning();
	}

	/// Add the specified task to this scheduler.
	void addTask(int id, int priority, Packet queue, Task task) {
	currentTcb = TaskControlBlock(list, id, priority, queue, task);
	list = currentTcb;
	blocks[id] = currentTcb;
	}

	/// Execute the tasks managed by this scheduler.
	void schedule() {
	currentTcb = list;
	while (currentTcb != null) {
	if (currentTcb.isHeldOrSuspended()) {
	currentTcb = currentTcb.link;
	} else {
	currentId = currentTcb.id;
	currentTcb = currentTcb.run();
	}
	}
	}

	/// Release a task that is currently blocked and return the next block to run.
	TaskControlBlock release(int id) {
	final TaskControlBlock tcb = blocks[id];
	if (tcb == null) return tcb;
	tcb.markAsNotHeld();
	if (tcb.priority > currentTcb.priority) return tcb;
	return currentTcb;
	}

	/// Block the currently executing task and return the next task control block
	/// to run. The blocked task will not be made runnable until it is explicitly
	/// released, even if new work is added to it.
	TaskControlBlock holdCurrent() {
	holdCount++;
	currentTcb.markAsHeld();
	return currentTcb.link;
	}

	/// Suspend the currently executing task and return the next task
	/// control block to run.
	/// If new work is added to the suspended task it will be made runnable.
	TaskControlBlock suspendCurrent() {
	currentTcb.markAsSuspended();
	return currentTcb;
	}

	/// Add the specified packet to the end of the worklist used by the task
	/// associated with the packet and make the task runnable if it is currently
	/// suspended.
	TaskControlBlock queue(Packet packet) {
	final TaskControlBlock t = blocks[packet.id];
	if (t == null) return t;
	queueCount++;
	packet.link = null;
	packet.id = currentId;
	return t.checkPriorityAdd(currentTcb, packet);
	}
	}

	/// A task control block manages a task and the queue of work packages
	/// associated with it.
	class TaskControlBlock {
	TaskControlBlock link;
	int id; // The id of this block.
	int priority; // The priority of this block.
	Packet queue; // The queue of packages to be processed by the task.
	Task task;
	int state;

	TaskControlBlock(this.link, this.id, this.priority, this.queue, this.task) {
	state = queue == null ? STATE_SUSPENDED : STATE_SUSPENDED_RUNNABLE;
	}

	/// The task is running and is currently scheduled.
	static const int STATE_RUNNING = 0;

	/// The task has packets left to process.
	static const int STATE_RUNNABLE = 1;

	/// The task is not currently running. The task is not blocked as such and may
	/// be started by the scheduler.
	static const int STATE_SUSPENDED = 2;

	/// The task is blocked and cannot be run until it is explicitly released.
	static const int STATE_HELD = 4;

	static const int STATE_SUSPENDED_RUNNABLE = STATE_SUSPENDED \| STATE_RUNNABLE;
	static const int STATE_NOT_HELD = ~STATE_HELD;

	void setRunning() {
	state = STATE_RUNNING;
	}

	void markAsNotHeld() {
	state = state & STATE_NOT_HELD;
	}

	void markAsHeld() {
	state = state \| STATE_HELD;
	}

	bool isHeldOrSuspended() {
	return (state & STATE_HELD) != 0 \|\| (state == STATE_SUSPENDED);
	}

	void markAsSuspended() {
	state = state \| STATE_SUSPENDED;
	}

	void markAsRunnable() {
	state = state \| STATE_RUNNABLE;
	}

	/// Runs this task, if it is ready to be run, and returns the next
	/// task to run.
	TaskControlBlock run() {
	Packet packet;
	if (state == STATE_SUSPENDED_RUNNABLE) {
	packet = queue;
	queue = packet.link;
	state = queue == null ? STATE_RUNNING : STATE_RUNNABLE;
	} else {
	packet = null;
	}
	return task.run(packet);
	}

	/// Adds a packet to the worklist of this block's task, marks this as
	/// runnable if necessary, and returns the next runnable object to run
	/// (the one with the highest priority).
	TaskControlBlock checkPriorityAdd(TaskControlBlock task, Packet packet) {
	if (queue == null) {
	queue = packet;
	markAsRunnable();
	if (priority > task.priority) return this;
	} else {
	queue = packet.addTo(queue);
	}
	return task;
	}

	@override
	String toString() => 'tcb { $task@$state }';
	}

	/// Abstract task that manipulates work packets.
	abstract class Task {
	Scheduler scheduler; // The scheduler that manages this task.

	Task(this.scheduler);

	TaskControlBlock run(Packet packet);
	}

	/// An idle task doesn't do any work itself but cycles control between the two
	/// device tasks.
	class IdleTask extends Task {
	int v1; // A seed value that controls how the device tasks are scheduled.
	int count; // The number of times this task should be scheduled.

	IdleTask(Scheduler scheduler, this.v1, this.count) : super(scheduler);

	@override
	TaskControlBlock run(Packet packet) {
	count--;
	if (count == 0) return scheduler.holdCurrent();
	if ((v1 & 1) == 0) {
	v1 = v1 >> 1;
	return scheduler.release(Richards.ID_DEVICE_A);
	}
	v1 = (v1 >> 1) ^ 0xD008;
	return scheduler.release(Richards.ID_DEVICE_B);
	}

	@override
	String toString() => 'IdleTask';
	}

	/// A task that suspends itself after each time it has been run to simulate
	/// waiting for data from an external device.
	class DeviceTask extends Task {
	Packet v1;

	DeviceTask(Scheduler scheduler) : super(scheduler);

	@override
	TaskControlBlock run(Packet packet) {
	if (packet == null) {
	if (v1 == null) return scheduler.suspendCurrent();
	final Packet v = v1;
	v1 = null;
	return scheduler.queue(v);
	}
	v1 = packet;
	return scheduler.holdCurrent();
	}

	@override
	String toString() => 'DeviceTask';
	}

	/// A task that manipulates work packets.
	class WorkerTask extends Task {
	int v1; // A seed used to specify how work packets are manipulated.
	int v2; // Another seed used to specify how work packets are manipulated.

	WorkerTask(Scheduler scheduler, this.v1, this.v2) : super(scheduler);

	@override
	TaskControlBlock run(Packet packet) {
	if (packet == null) {
	return scheduler.suspendCurrent();
	}
	if (v1 == Richards.ID_HANDLER_A) {
	v1 = Richards.ID_HANDLER_B;
	} else {
	v1 = Richards.ID_HANDLER_A;
	}
	packet.id = v1;
	packet.a1 = 0;
	for (int i = 0; i < Richards.DATA_SIZE; i++) {
	v2++;
	if (v2 > 26) v2 = 1;
	packet.a2[i] = v2;
	}
	return scheduler.queue(packet);
	}

	@override
	String toString() => 'WorkerTask';
	}

	/// A task that manipulates work packets and then suspends itself.
	class HandlerTask extends Task {
	Packet v1;
	Packet v2;

	HandlerTask(Scheduler scheduler) : super(scheduler);

	@override
	TaskControlBlock run(Packet packet) {
	if (packet != null) {
	if (packet.kind == Richards.KIND_WORK) {
	v1 = packet.addTo(v1);
	} else {
	v2 = packet.addTo(v2);
	}
	}
	if (v1 != null) {
	final int count = v1.a1;
	Packet v;
	if (count < Richards.DATA_SIZE) {
	if (v2 != null) {
	v = v2;
	v2 = v2.link;
	v.a1 = v1.a2[count];
	v1.a1 = count + 1;
	return scheduler.queue(v);
	}
	} else {
	v = v1;
	v1 = v1.link;
	return scheduler.queue(v);
	}
	}
	return scheduler.suspendCurrent();
	}

	@override
	String toString() => 'HandlerTask';
	}

	/// A simple package of data that is manipulated by the tasks. The exact layout
	/// of the payload data carried by a packet is not importaint, and neither is
	/// the nature of the work performed on packets by the tasks. Besides carrying
	/// data, packets form linked lists and are hence used both as data and
	/// worklists.
	class Packet {
	Packet link; // The tail of the linked list of packets.
	int id; // An ID for this packet.
	int kind; // The type of this packet.
	int a1 = 0;

	List<int> a2 = List(Richards.DATA_SIZE);

	Packet(this.link, this.id, this.kind);

	/// Add this packet to the end of a worklist, and return the worklist.
	Packet addTo(Packet queue) {
	link = null;
	if (queue == null) return this;
	Packet peek, next = queue;
	while ((peek = next.link) != null) {
	next = peek;
	}
	next.link = this;
	return queue;
	}

	@override
	String toString() => 'Packet';
	}